CURRICULUM VITAE Dr. Bernardo Mendoza Santoyo Expediente
Transcription
CURRICULUM VITAE Dr. Bernardo Mendoza Santoyo Expediente
CURRICULUM VITAE (versión electrónica navegable en http://aida.cio.mx/cvbms.pdf) Dr. Bernardo Mendoza Santoyo Expediente 12084 3 de febrero de 2009 Índice Portada i Contenidos ii Semblanza 1 Resumen de Actividades del quinquenio 2003-2008 8 Grados Académicos 10 Campos de Especialidad 10 Experiencia Profesional 11 Experiencia Docente 12 Producción Cientı́fica Artı́culos sin arbitraje . . . . . . . . . . . Artı́culos con arbitraje . . . . . . . . . . . Artı́culos en libros con arbitraje . . . . . Artı́culos en docencia con arbitraje . . . Memorias in extenso con arbitraje . . . . Artı́culos interdiciplinarios con arbitraje Capı́tulos en libros . . . . . . . . . . . . . . Artı́culos enviados con arbitraje . . . . . Artı́culos en preparación con arbitraje . 13 13 13 20 20 20 22 22 23 23 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Editor Cientı́fico 24 Programas de Computo Registrados 24 Comités Cientı́ficos Internacionales 24 Comités Evaluadores 24 Organización de Congresos 25 Reuniones de Trabajo 25 ii/74 Invitación a Cursos Cortos 25 Estancias de Investigación 26 Formación de Personal Académico 27 Posdoctorantes 29 Sinodal de Tesis 29 Seminarios Cientı́ficos 29 Artı́culos de Divulgación 31 Seminarios de Divulgación 32 Congresos Nacionales 32 Congresos Internacionales 38 Moderador en Congresos 49 Citas Bibliográficas 49 Distinciones 67 Apoyo a Proyectos de Investigación 68 Formación de Grupos 69 Totales 72 Referencias 73 Intereses Personales 74 iii/74 CURRICULUM VITAE NOMBRE: Bernardo Mendoza Santoyo Lugar de Nacimiento: Silao, Guanajuato Fecha de Nacimiento: 13 de Junio de 1961, 47 años. Miembro del Sistema Nacional de Investigadores Area de Ciencias Exactas, S.N.I. Nivel III Exp. 12084 Miembro de la Academia Mexicana de Ciencias DIRECCION: Centro de Investigaciones en Optica, A.C. Loma del Bosque 115, León, GTO, 37150, México tel (+52-477) 441-4200 fax (+52-477) 441-4209 email: [email protected] 1 Semblanza A continuación presento un resumen de mi carrera cientı́fica y de los logros que he obtenido a lo largo de ella desde que me incorporé al Centro de Investigaciones en Optica, A.C. (CIO) en Agosto de 1991 con el programa de repatriación del CONACYT. En el CIO he establecido una lı́nea de investigación sólida y consistente en el tema de las propiedades ópticas (lineales y no-lineales) de superficies e interfaces de materiales metálicos, semiconductores y nanoscópicos. La madurez y liderazgo nacional e internacional que tengo en este tema de investigación cientı́fica, además de ser palpable en la calidad de mi producción cientı́fica y de recursos humanos, queda también de manifiesto en la publicación de un número de la prestigiosa revista, arbitreada y de circulación internacional, physica status solidi, del cual soy el Editor Invitado y en la cual aparecen los artı́culos de investigación cientı́fica que marcan la vanguardia del tema (ver 8 en la página 24). Ası́ mismo, fungı́ como Chairman del también prestigioso congreso Optics of Surfaces and Interfaces (OSI-V) (ver 12 en la página 25) que en sus ediciones pasadas fue realizado en diferentes lugares de Europa. En esa ocasión el comite europeo de EPIOPTICS decidió, cederme el honor de organizarlo en México, basandose en mis propios logros al tema. Actualmente soy miembro del comité cientı́fico internacional tanto del congreso bianual Optics of Surfaces and Interfaces y de la escuela de verano, también bianual, Epioptics, que se realiza en el prestigiado centro Ettore Majorana en Erice, Sicilia, Italia. De esta escuela también soy profesor de los cursos de vanguardia que se dan sobre el tema (ver 14 en la página 25). También, por invitación, he publicado dos artı́culos de revisión en esta 1/74 área, uno en la revista Surface and Interface Analysis (ver 7.2.43 en la página 17) y el otro en la revista Journal of Physics: Condensed Matter (ver 7.2.56 en la página 18) y he recibido la invitación de la casa editorial WILEY-VCH (Alemania) para editar un libro sobre el tema, mismo que quisierá comenzar en el año 2009. Ası́ mismo, he formado un grupo de investigadores que se dedican exclusivamente al estudio de las propiedades ópticas de superficies. De hecho, el grupo de Propiedades Opticas de Superficies del CIO, bajo mi dirección, esta formado por tres investigadores de tiempo completo, dos de los cuales realizarón su trabajo doctoral bajo mi supervición y fueron repatriados después de una estancia postdoctoral en el extranjero. Actualmente uno de ellos trabaja en la Universidad de Guadalajara. Este grupo estudia en gran medida las ideas generadas a través de mi carrera cientı́fica, y de hecho han comenzado a publicar también por su cuenta tomando estas ideas, en estrecha colaboración conmigo. De hecho a la fecha, los tres investigadores cuentan con proyectos propios de investigación y alumnos de maestrı́a (ver 28.1 en la página 69). Recientemente el CIO contrató dos investigadores para trabajar en mi grupo, de forma tal que muy pronto comenzaremos ha explorar la parte experimental de mi tema de investigación (ver 28.1 en la página 69). La motivación para haberme concentrado en estos temas de investigación, se basa en la gran versatilidad que las espectroscopı́as ópticas de superficie ofrecen para el estudio fı́sico de las mismas y por ello su gran potencial de aplicación tanto en problemas fundamentales como aplicados. Estas técnicas pueden ser utilizadas fuera de condiciones de ultra alto vacı́o, que son necesarias en otro tipo de pruebas superficiales, y aparte son no-destructivas, no-invasivas, se pueden llevar a cabo en tiempo real e in-situ, y cubren un amplio rango espectral que va desde el infrarojo hasta el ultravioleta (pasando por todo el visible), con lo cual se pueden estudiar diversos tipos de resonancias de gran interés. Con las técnicas de espectroscopı́a óptica superficial se pueden estudiar fenómenos tan diversos como la simetrı́a y asimetrı́a cristalina de una superficie, y sus distintas reconstrucciones geométricas, la adsorción y dopaje superficial, efectos de campos eléctricos en superficies, vibración de moléculas sobre superficies, crecimiento epitaxial atómico y molecular en tiempo real, etc., hasta tópicos tan diversos como sublimación capa-a-capa de superficies por efectos térmicos y fenómenos superficiales en sistemas orgánicos. Recientemente estas pruebas ópticas han cobrado gran auge en el estudio de nanoparticulas y he incursionado en el estudio de la respuesta óptica del segundo armónico en sistemas de escala nanoscópica. Mi trabajo de investigación ha permitido el desarrollo de modelos teóricos que sirven para la interpretación fı́sica de los resultados experimentales de estas técnicas, y en particular me he concentrado en dos espectroscopı́as. La primera es la llamada Reflectance Anisotropy Spectroscopy (RAS) mediante la cual es posible cancelar la respuesta isotrópica del bulto y estudiar ópticamente superficies anisotrópicas. Una variante de 2/74 esta técnica, es la Reflectance Difference Spectroscopy (RDS) que es utilizada para estudiar adsorción de átomos o moléculas en superficies. La segunda técnica se basa en la respuesta óptica no-lineal (a segundo orden) del material y contempla a la suma y diferencia de frequencias (o Sum and Difference frequency generation-SFG/DFG) y a la generación del segundo armónico (o Second Harmonic Generation-SHG). Para materiales centrosimétricos, la respuesta óptica no-lineal a segundo orden y bajo la aproximación dipolar, viene exclusivamente de la superficie. De esta forma, tanto RAS/RDS como SHG/SFG/DFG son pruebas de espectroscopı́a óptica especı́ficamente superficiales, ya que la contribución del bulto se anula por simetrı́a. Con mayor énfasis me he concentrado en la espectroscopı́a óptica no-lineal, ya que es un tema que no habı́a recibido la atención teórica adecuada y el reciente desarrollo de los láseres entonables de alta potencia en el rango de los femtosegundos ha permitido que esta prueba sea ahora muy utilizada. De hecho en el campo de los semiconductores, los artı́culos previos a mis trabajos, solo eran de caracter fenomenológico y por lo tanto no ofrecı́an un marco teórico adecuado para hacer cálculos explı́citos de la susceptibilidad óptica no-lineal. Con los modelos teóricos propuestos y desarrollados en mis diferentes artı́culos, se ha podido demostrar que es posible dar una interpretación fı́sica de los espectros medidos y que estos pueden ser relacionados con diferentes fenómenos de la superficie a escala atómica. Cabe mencionar que a pesar de que la luz visible tiene una longitud de onda mucho más grande que las distancias interatómicas de la mayorı́a de los materiales, las técnicas sobre las cuales se ha trabajado teóricamente, permiten estudiar superficies a escala atómica. Los trabajos reportados a continuación se pueden clasificar como sigue: 1.1 Modelos de enlaces polarizables o semiclásicos: 1.1.1 Continuos, donde se supone una distribución continua de entidades polarizables. Dentro de estos modelos se ha logrado dar soluciones analı́ticas a la respuesta óptica no-lineal de un medio semi-infinito, con la gran ventaja de que dicha respuesta depende solo de las propiedades macroscópicas ópticas lineales del bulto del material. Se pueden hacer predicciones espectrales para una gran clase de materiales. Por ejemplo con estos modelos se pueden predecir la orientación de moléculas sobre superficies metálicas con el uso de SFG/DFG. También se pueden estudiar las novedosas nanopraticulas. 1.1.2 Discretos, donde el cristal se remplaza por un arreglo periódico de enlaces polarizables localizados entre los átomos del sistema. Aquı́, se resuelve de manera exacta el problema del campo local para este tipo de modelos. La sensibilidad de la respuesta óptica lineal y no-lineal al campo local superficial permite relacionar varias estructuras espectrales tanto 3/74 en RAS como en SHG, a la morfologı́a atómica de la superficie. También se ha estudiado el efecto del desorden espacial en sistemas de entidades polarizables. 1.2 Modelos de estructura de bandas o cuánticos: 1.2.1 Discretos, donde el hamiltoniano y las funciones de onda del sistema se toman bajo la aproximación de enlace fuerte o Tight-Binding. Con este modelo se explica, por primera vez, desde el punto de vista microscópico el espectro de SHG para una superficie limpia de Si en la cara (100) y como función de la adsorción de H. Se encuentra que tanto la respuesta perpendicular como paralela a la superficie son igualmente importantes. Se predicen varias resonancias que han sido medidas. También se predice el efecto que un campo eléctrico estático fuertemente confinado a la superficie tiene en el SHG. Corroborandose dicha predicción con experimentos muy finos de absorción de Boro en Silicio cara (100). Se propone al SHG como una herramienta óptica para poder distinguir entre diferentes tipos de reconstrucción superficial. La combinación de las ideas de 1.2.1 y este punto, da por primera vez una explicación teórica al espectro de RAS para una superficie de Si cara (110) limpia de adsorbatos. 1.2.2 Extendidos, donde el hamiltoniano del sistema se toma bajo la DFT (Density Functional Theory) dentro de la LDA (Local Density Approximation) y las funciones de onda se expanden en ondas planas. Estos modelos se han trabajado dentro del marco de primeros principios o ab-initio. En particular se calculan por primera vez los efectos de muchos cuerpos llamados de Cuasi Partı́cula (CP) en el SHG, obteniéndose un resultado muy importante: las superficies ideales presentan correcciones de CP triviales mediante los cuales solo se observan corrimientos rı́gidos en los espectros, mientras que en las superficies reconstruidas los efectos de CP mezclan y redistribuyen los pesos de las diferentes transiciones involucradas que dan origen a las diferentes resonancias espectrales. También, estos modelos nos permiten una comparación directa con los resultados del punto 1.1 para de esta manera ver las ventajas y desventajas de ambos cálculos. Estos métodos requieren de un gran poder de computo, para lo cual hemos desarrollado una serie de programas para la administración eficiente de los cálculos. Dichos programas han sido registrados ante el Instituto Nacional de Derechos de Autor para poderlos poner a la disposisión de la comunidad. (ver 9 en la página 24). Los modelos arriba mencionados han sido exitosos en la descripción de RAS y SHG en gran variedad de sistemas y su impacto en la comunidad cientı́fica internacional se 4/74 puede verificar a través de las mismas publicaciones y de las citas obtenidas. En particular resalto el artı́culo de revisión de G. Lüpke (Surf. Sci. Reports 35, 75 (1999)), y el libro especializado de A. Liebsch (Electronic Excitations at Metal Surfaces, Plenum, N.Y. 1998), en donde se habla extensamente de los modelos arriba mencionados e inclusive reproduce varias de las formulas básicas de los modelos del punto 1.1. También, recientemente grupos experimentales del NRC de Canada, Universidad de Texas en Austin y de la Universidad Técnica de Berlin, hacen comparaciones éxitosas de los resultados teóricos con sus espectros experimentales, de lo cual se obtienen importantes conclusiones sobre la fı́sica de estos fenómenos superficiales. La experiencia y madurez adquirida en estos años es también palpable en los siguientes hechos: • Nivel III del Sistema Nacional de Investigadores. • Promovido a Investigador Titular D desde febrero del 2008, siendo E la máxima categorı́a. • 4 estudiantes de doctorado graduados (todos son miembros del SNI) • 6 estudiantes de maestrı́a graduados (trabajando en actividades académicas). • 1 estudiante de licenciatura graduado (trabajando en actividades académicas). • 4 estudiantes realizando tesis de posgrado y licenciatura. • Formación de un grupo de trabajo en el CIO que se dedica exclusivamente al estudio de las propiedades ópticas de superficies e interfaces, formado por 5 investigadores de tiempo completo, un posdoc y alumnos. • Un total de 113 artı́culos. (ver 29 en la página 72) • Más de 555 referencias a la fecha. (ver 25 en la página 49) • Editor Invitado de un número de physica status solidi (ver 8 en la página 24). • Chairman del Congreso Internacional Optics of Surfaces and Interfaces (OSI-V) (ver 12 en la página 25) • Participación en dos comités internacionales (ver 10 en la página 24) • Estancia Sabática con el Profesor Rodolfo Del Sole del Departamento de Fı́sica de la Universida de Roma II, apoyado por el CONACYT. • Estancia Sabática con el Profesor John Sipe del Departamento de Fı́sica de la Universidad de Toronto (Considerada como top 10-international por la revista The Scientist), con apoyo de Photonics Research Ontario. • Profesor y organizador de la International School of Solid State Physics: EPIOPTICS en el Ettore Majorana Center for Scientific Culture, Erice, Italia. (ver 14 en la página 25) 5/74 • Artı́culo de revisión por invitación sobre SHG en el Journal of Surface and Interface Analysis (ver 7.2.43 en la página 17) y sobre RAS en el Journal of Physics: Condensed Matter (ver 7.2.56 en la página 18). • 10 proyectos en los últimos 15 años. El más reciente termina en diciembre del 2010. • 3 capı́tulos en libros especializados sobre el tema de mi investigación. (ver 7.7 en la página 22). • Proyecto de Colaboración ANUIES-DAAD Alemania por tres años. • Proyecto de Colaboración CONACYT-CNR Italia por tres años. • Proyecto de Colaboración AMC-Fundación México-Estados Unidos para la Ciencia por dos meses. • Soy árbitro tanto de proyectos como del padrón de postgrados de excelencia del CONACYT, de las revistas Physical Review B, Physical Review Letters, Canadian Journal of Physics y de proyectos del CNR de Italia, ası́ como miembro del comité internacional de EPIOPTICS, que es un consorcio Europeo que se dedica al estudio de superficies por medio de la óptica. He trabajado también en otros temas como son superconductividad, plasmones en sistemas de dimensionalidad reducida, dispersión de luz, e inclusive he colaborado con biólogos orales en las propiedades reológicas de la saliva humana. Llevo también 17 años dando clases en el posgrado del CIO y en los ú’timos 10 años en la licenciatura de Fı́sica e Ing. Fı́sica que se imparte conjuntamente con el Instituto de Fı́sica de la U. de Guanajuato. Mis planes a futuro, junto con los de mi grupo de investigación, consisten en la diversificación de los modelos arriba mencionados y en continuar con los desarrollos teóricos que permitan relajar varias de las aproximaciones hechas e incorporar nuevos efectos fı́sicos. Ası́ como incursionar en el aspecto experimental de los temas mencionados con anterioridad. Por ejemplo estudiar los efectos de vectores de onda finitos (esto es, relajar la aproximación de longitud de onda larga), y comparar la norma longitudinal con la norma transversal en el cálculo de la respuesta microscópica no-lineal. Analizar la contribución a SHG de portadores de carga en la banda de conducción de semiconductores pre-excitados. Incluir los efectos de excitones, campo-local, y espı́n-orbita, en las propiedades ópticas de superficies. De hecho, ya hemos incluido exitosamente los últimos en la técnica de RAS. (ver 7.2.58 en la página 18). Recientemente, he comenzado a investigar el control de corrientes electrónicas de espı́n mediante fotones. Este tema, denominado, optoespintrónica, es el tema de mi nuevo proyecto apoyado por el CONACYT. (ver 27 en la página 68). De hecho ya he publicado el primer artı́culo sobre el tema (ver 7.2.69 en la página 19) y estamos terminando de escribir dos artı́culo más en donde ya hemos generalizado el formalismo anterior para 6/74 su aplicación en bultos bajo presión y superficies de semiconductores. (ver 7.9.3 y 7.9.5 en la página 23). También, junto con investigadores de la U. de Guadalajara, la U. del Nordeste de Argentina y de la UNAM, he comenzado a estudiar la respuesta dielectrica de metamateriales. Ya se cuenta con un primer manuscrito que ha sido enviado a la revista Physical Review B (ver 7.8.1 en la página 23). De igual forma, en colaboración con el posdoctorante del grupo hemos logrado obtener un procedimento totalmente novedoso para calcular dicha respuesta (ver 7.9.9 en la página 23), y estamos trabajando sobre su generalización (ver 7.9.8 en la página 23). Los resultados obtenidos a la fecha son realmente sorprendentes. En este año estoy contemplando la publicación de al menos 10 artı́culoes en diferentes temas de investigación (ver 7.9 en la página 23), que confirman mi compromiso a seguir realizando investigación de vanguardia del más alto nivel. Los temas de estos manuscritos (la gran mayoria ya en revisión interna), muestran la versatilidad y la capacidad de abordar temas de frontera con resultados importantes y publicables a corto plazo. En este rubro, menciono que el año pasado obtuve un proyecto del Consejo de Ciencia y Tecnologı́a del Estado de Guanajuato (CONCYTEG) para la construcción de un glucómetro óptico no invasivo (ver 27.2 en la página 68). Este proyecto que estoy realizando en colaboración con mi alumno de doctorado, el M. en C. Luis Adan Martı́nez Jiménez (ver 16.4.3 en la página 28), muestra la diversidad de temas sobre las que versan mi investigación. De hecho el tema de tesis del M. en C. Martı́nez, es sobre un sistema de visualización para debiles visuales o ciegos. 7/74 2 Resumen de Actividades del quinquenio 2004-2008 A continuación hago un breve resumen puntual de mis logros más relevantes en el quinquenio 2004-2008, sin embargo hago la aclaración de que el presente Curriculum Vitae contiene la información de toda mi carrera cientı́fica. 2.1 Promovido a Investigador Titular D desde febrero del 2008, siendo “E” la máxima categorı́a en el CIO. 2.2 11 clases en el posgrado de Maestrı́a y Doctorado del CIO. 2.3 7 clases en la licenciatura de Fı́sica e Ingenierı́a Fı́sica del Instituto de Fı́sica de la Universidad de Guanajuato. 2.4 3 alumnos graduados de Maestrı́a en el CIO (ver 16 en la página 27). 2.5 Un alumno graduado de Licenciatura en Fı́sica de la U. de Guadalajara. (ver 16 en la página 27). 2.6 3 alumnos de doctorado en proceso (ver 16.4 en la página 28). 2.7 Un alumno de licenciatura en proceso (ver 16.4 en la página 28). 2.8 16 artı́culos con arbitraje (ver 7.2 en la página 13). 2.9 3 capı́tulos en Libros (ver 7.7 en la página 22). 2.10 301 Citas para un total de 555 citas. (ver 25 en la página 49). 2.11 Un programa de Computo en tramite de registro en el Instituto Nacional de Derechos de Autor, hecho en colaboración con dos de mis alumnos de posgrado (ver 9 en la página 24). 2.12 5 memoria in-extenso con arbitraje (ver 7.5 en la página 20). 2.13 Un artı́culo sin arbitraje (ver 7.1 en la página 13). 2.14 Miembro de dos comités cientı́ficos internacionales (ver 10 en la página 24). 2.15 Miembro del Comité Externo de Evaluación del CICESE (ver 11 en la página 24). 2.16 Profesor de 5 cursos cortos en Escuelas de Fı́sica Internacionales (ver 14 en la página 25). 2.17 Estancia sabática en el prestigioso departamento de Fı́sica de la Universidad de Toronto (ver 15 en la página 26). 2.18 Sinodal de 4 tesis (ver 18 en la página 29). 2.19 8 seminarios de divulgación cientı́fica (ver 21 en la página 31). 2.20 4 proyectos de investigación por un total de $3,043,500 pesos (ver 27 en la página 68). 8/74 2.21 Un grupo de trabajo dedicado exclusivamente al estudio de los temas de investigación objeto de mi área de estudio, formado por seis investigadores con doctorado, posdoctorante y estudiantes. Cuatro de los investigadores trabajan en mi grupo del CIO. (ver 28.1 en la página 69). Cabe mencionar, que contamos con un Cluster de computo númerico de alto rendimiento y de uso exclusivo, que fué adquirido con varios proyectos del CONACyT. Como se desprende del resumen anterior y de mi Curriculum Vitae completo, a los 17 años de haber comenzado mi carrera cientı́fica en México, he demostrado ser un investigador cientı́fico consolidado, con una productividad constante y en temas diversos que siguen una linea clara de investigación cientı́fica y con un número sobresaliente de citas a mi trabajo. Ası́ mismo, he desarrollado una gran actividad académica tanto en la generación de recursos humanos, en todos los niveles, como en la impartición de clases de posgrado y licenciatura. También he realizado importantes actividades de divulgación cientı́fica y soy el único investigador del CIO que tiene en proceso de registro un programa de computo cientı́fico. Participo en varios comités académicos-cientı́ficos activamente y mi compromiso por ser un cientı́fico completo y destacado queda de manifiesto en este documento. Por lo tanto, pido al comité evaluador considere la pertinencia de que continué en el nivel III del Sistema Nacional de Investigadores. 9/74 3 Grados Académicos 3.1 Licenciatura: Fı́sica. Institución: Universidad Autónoma Metropolitana-Iztapalapa. Tı́tulo Obtenido: Licenciado en Fı́sica. 1984 Fecha de exámen profesional: no se requiere. Nombre de la tesis presentada: no se requiere. 3.2 Maestrı́a: Fı́sica. Institución: State University of New York at Buffalo. Grado obtenido: Master in Arts. Fecha de exámen: 29 de Enero de 1988. Nombre de la tésis presentada: A Review of the Experimental Situation for High Tc Superconductors. 3.3 Doctorado: Fı́sica. Institución: State University of New York at Buffalo. Grado obtenido: Doctor of Philosophy. Fecha de exámen: 31 de Agosto de 1989. Nombre de la tésis presentada: Collective Excitations and Superconductivity in Reduced Dimensional Systems-Possible Mechanism for High Tc . 4 Campos de Especialidad 4.1 Óptica: 4.1.1 4.1.2 4.1.3 4.1.4 4.1.5 4.1.6 Propiedades Opticas Lineales y No-Lineales de la Materia. Generación del Segundo Armónico en medios cristalinos y amorfos. Espectroscopı́a de Reflectancia Anisotrópica. Fenómenos Opticos de Superficies. Espintrónica asistida por fotones. Propiedades ópticas de metamateriales. 4.2 Materia Condensada: 4.2.1 Plasmones en sistemas de dimensión reducida. 4.2.2 Superconductividad. 4.3 Gravitación: 4.3.1 Acoplamiento gravitacional con sistemas cuánticos. 10/74 4.4 Biofı́sica: 4.4.1 Propiedades reológicas de la Saliva Humana. 5 Experiencia Profesional 5.1 Investigador Titular D. Febrero del 2008 a la fecha. Centro de Investigaciones en Optica, León, México. 5.2 Profesor Visitante. Julio del 2004 a Agosto del 2005. University of Toronto Departamento de Fı́sica. Toronto, Canada Año Sabático con el Profesor John Sipe. 5.3 Investigador Titular C. Mayo del 2001 a Mayo del 2008. Centro de Investigaciones en Optica, León, México. 5.4 Investigador Titular B. Enero de 1996 a Mayo de 2001. Centro de Investigaciones en Optica, León, México. 5.5 Profesor Visitante. Septiembre de 1997 a Agosto de 1998. Universita degli Studi di Roma II, Tor Vergata Departamento de Fı́sica. Roma, Italia. Año Sabático con el Profesor Rodolfo Del Sole. 5.6 Investigador Titular A. Septiembre de 1992 a Diciembre de 1995. Centro de Investigaciones en Optica, León, México. 11/74 5.7 Investigador Titular A. Agosto 1991 a Agosto 1992. bajo el programa del Fondo para Retener en México Y Repatriar a los Investigadores Mexicanos. Centro de Investigaciones en Optica, León, México. 5.8 Investigador Asociado. Department of Physics: Condensed Matter Theory Group. Indiana University, Bloomington, Indiana, E.U.A. Septiembre 1989 a Agosto 1991. 5.9 Profesor Auxiliar. Departamento de Fı́sica. Universidad Autónoma Metropolitana-Iztapalapa. Febrero 1982 a Agosto 1984. 6 Experiencia Docente 6.1 Centro de Investigaciones en Optica, A. C. Agosto 1991 a la fecha. Nivel maestrı́a y doctorado. Mecánica Cuántica, Optica No-lineal, Temas selectos en Interacción RadiaciónMateria, Electromagnétismo, y Métodos Matemáticos. 6.2 Universidad de Guanajuato, Instituto de Fı́sica. Enero del 2001 a la fecha. Nivel licenciatura. Fı́sica, Eléctricidad y Magnétismo, Cálculo, Optica No-lineal y Óptica Cuántica. 6.3 Instituto Tecnológico y de Estudios Superiores de Monterrey-Campus León Profesor por Asignatura Agosto 1991 a Diciembre del 2000. Nivel licenciatura. Fı́sica I, Eléctricidad y Magnétismo, Mecánica, Probabilidad, y Cálculo 6.4 State University of New York at Buffalo. Department of Physics and Astronomy. Profesor por asignatura. Fı́sica (Eléctricidad y Magnétismo) 1/88 a 5/88. Fı́sica (Mecánica) 8/88 a 5/89. 12/74 6.5 State University of New York at Buffalo. Department of Physics and Astronomy. Profesor Ayudante. Fı́sica (Eléctricidad y Magnétismo, Mecánica) 8/84 a 12/87. 6.6 Universidad Autónoma Metropolitana-Iztapalapa. Departamento de Fı́sica. Profesor Ayudante. Fı́sica (Eléctricidad y Magnétismo, Mecánica) 2/82 a 7/84. 7 Producción Cientı́fica: Total: 113, ver sección Totales (29) en la página 72. (Nota: los alumnos estan en italicas y los investigadores de mi grupo en Sans-Seriff) 7.1 Artı́culos sin arbitraje: 7.1.1 Aproximación no Relativista de la Ecuación de Dirac en presencia de Gravitación y en Sistemas de Referencia no Inerciales, B. S. Mendoza, Universidad Autónoma Metropolitana-Iztapalapa. Reporte interno 1984. 7.1.2 Respuesta macroscópica de metamateriales nanoestructurados, G. Ortiz, B.E. Martı́nez-Zérega, Bernardo S. Mendoza, and W.L Mochán, Escuela de Verano en Fı́sica XVI: La Visión Molecular de la Materia, 2008. 7.2 Artı́culos con arbitraje: 7.2.1 Láser de nitrógeno a presión atmosférica, A. Porta, S. Godoy, B.S. Mendoza, M. Arreola y A. Garcı́a, Instrumentación y Desarrollo 1, 35-40 (1982). citas página: 49 7.2.2 A heuristic approach to the multi-mode theory of superconductivity and the effect of mode damping, Y.C. Lee, B.S. Mendoza and D.S. Chuu, Supercond. Sci. Technol. 1, 271-275 (1989). 7.2.3 Superconductivity in slender structures, Y.C. Lee, B.S. Mendoza and S.E. Ulloa, Supercond. Sci. Technol. 1, 352-359 (1989). citas página: 49 7.2.4 Possible high Tc superconductivity in thin wires, Y.C. Lee and B.S. Mendoza, Phys. Rev. B 39, 4776 (1989). citas página: 49 13/74 7.2.5 Possible superconducting mechanism for high Tc in quasi-one dimensional multiwire structures, B.S. Mendoza and Y.C. Lee, Phys. Rev. B 40, 10946 (1989). citas página: 50 7.2.6 Collective electronic oscillations in slender structures at finite temperatures, B.S. Mendoza and Y.C. Lee, Phys. Rev. B 40, 12063 (1989). citas página: 50 7.2.7 Hydrodynamic theory of intrasubband plasmons in quasi-one-dimensional systems, B.S. Mendoza and W.L. Schaich, Phys. Rev. B 43, 6590 (1991). citas página: 50 7.2.8 Additional intersubband plasmons in quasi-one-dimensional systems, B.S. Mendoza and W.L. Schaich, Phys. Rev. B 43, 9275 (1991). citas página: 50 7.2.9 A Simple Model of Second-Harmonic Generation, W.L. Schaich and B.S. Mendoza, Phys. Rev. B 45, 14279 (1992). citas página: 51 7.2.10 A Theoretical Model for Second Harmonic Generation in Silicon, B.S. Mendoza, Journal of Physics: Condensed Matter 33A, A181 (1993). citas página: 52 7.2.11 Second Harmonic Generation at Crystal Surfaces, W.L. Mochán and B.S. Mendoza, Journal of Physics: Condensed Matter 33A, A183 (1993). citas página: 52 7.2.12 Generalized hydrodynamic model of inhomogeneous conductor in three, two and one dimensions, M. del Castillo, W.L. Mochán and B.S. Mendoza, Journal of Physics: Condensed Matter 33A, A393 (1993). citas página: 52 7.2.13 Enhancement of third-order nonlinear optical susceptibility in Si quantum wires, R. Chen, D.L. Lin and B. Mendoza, Phys. Rev. B 48, 11879 (1993). citas página: 52 7.2.14 A model for second harmonic generation in a two-dimensional array of quantum dots, Bernardo S. Mendoza, Optical Review 1, 223-226 (1994). 7.2.15 Hydrodynamic model for second-harmonic generation at conductor surfaces with continuous profiles, J. Maytorena, W.L. Mochán and B.S. Mendoza, Phys. Rev. B 51, 2556-2562 (1995). citas página: 53 7.2.16 Model for great enhancement s of second harmonic generation in quantum dots, A. Guerrero and Bernardo S. Mendoza, J. Opt. Soc. Am. B 12, 559-569 (1995). citas página: 53 14/74 7.2.17 Plasmons in a spatially modulated quasi-one-dimensional quantum wire, Bernardo S. Mendoza, Marcelo del Castillo-Mussot and W. Luis Mochán, Phys. Rev. B 53, 1026-1029 (1996). citas página: 53 7.2.18 Exactly solvable model of surface second harmonic generation, Bernardo S. Mendoza and W. Luis Mochán, Phys. Rev. B 53, 4999-5006 (1996). Erratum: Phys. Rev. B 61, 16243 (2000). citas página: 54 7.2.19 Local Field Effect in the Second Harmonic Generation Spectra of Si Surfaces, Bernardo S. Mendoza and W. Luis Mochán, Phys. Rev. B Rapid Communications 53, 10473 (1996). citas página: 54 7.2.20 Polarizable-bond model for second-harmonic generation, Bernardo S. Mendoza and W. Luis Mochán, Phys. Rev. B 55, 2489-2502 (1997). citas página: 55 7.2.21 Second harmonic generation from disordered 1D chains of polarizable spheres, J. Cruz, E. Jonguitud and Bernardo S. Mendoza, Physica A 241, 12-16 (1997). 7.2.22 Theory of surface sum frequency generation spectroscopy, Jesús A. Maytorena, Bernardo S. Mendoza, and W. Luis Mochán, Phys. Rev. B 57, 2569-2579 (1998). citas página: 56 7.2.23 Hydrodynamic model for sum and difference frequency generation at metal surfaces, Jesús A. Maytorena, W. Luis Mochán and Bernardo S. Mendoza, Phys. Rev. B 57, 2580-2585 (1998). citas página: 56 7.2.24 Theory of optical reflectance anisotropy of the natural Si(110) surfaces, Bernardo S. Mendoza, R. Del Sole, and A. Shkrebtti, Phys. Rev. B Rapid Communications 57, 12709 (1998). citas página: 56 7.2.25 Energy conservation and the Manley-Rowe relations in surface non-linear-optical spectroscopy, A.V. Petukhov, Vera L. Brudny, W. Luis Mochán, J. Maytorena, Bernardo S. Mendoza and Th. Rasing, Phys. Rev. Lett. 81, 566-569 (1998). citas página: 57 7.2.26 Magnetic dipolium model of magnetization-induced surface second harmonic generation, V.L. Brudny, W.L. Mochán, B.S. Mendoza, A.V. Petukhov and Th. Rasing, IEEE Trans. Magn. 34, 1048-1050 (1998). citas página: 57 7.2.27 Fiber-as-phase-object approximation in light scattering experiments, A. Starodumov, L. Zenteno and Bernardo S. Mendoza, Journal of Modern Optics, Letter 45, 1629-1635 (1998). 15/74 7.2.28 Microscopic theory of second-harmonic-generation at the Si(100) surface, Bernardo S. Mendoza, Andrea Gaggiotti, and Rodolfo Del Sole, Phys. Rev. Lett. 81, 3781-3784 (1998). citas página: 57 7.2.29 A model for second harmonic generation form magnetized surfaces, Vera L. Brundy, W. Luis Mochán, A.V. Pethukov, T. Raising and Bernardo S. Mendoza, Phys. Stat. Sol. (a) 170, 227-234 (1998). 7.2.30 Microscopic theory of second-harmonic-generation at the Si(100)2 × 1 surface, Bernardo S. Mendoza, Andrea Gaggiotti, and Rodolfo Del Sole, Phys. Stat. Sol. (a) 170, 343-348 (1998). citas página: 58 − 7.2.31 Visible-infrared difference frequency generation at CN covered Au, W. Luis Mochán, Jesús A. Maytorena and Bernardo S. Mendoza, Phys. Stat. Sol. (a) 170, 357-364 (1998). citas página: 58 7.2.32 Energy exchange in second-order nonlinear optics in centrosymmetric media, A.V. Petukhov, Bernardo S. Mendoza, Vera L. Brundy, W. Luis Mochán, J. Maytorena, and Th. Rasing, Phys. Stat. Sol. (a) 170, 417-422 (1998). 7.2.33 DC-electric-field modified second-harmonic-generation at the Si(100) surface, N. Arzate, J. Mejı́a, Bernardo S. Mendoza, and Rodolfo Del Sole, Appl. Phys. B 68, 629-632 (1999). citas página: 58 7.2.34 Ab initio optical properties of Si(100), Maurizia Palummo, Giovanni Onida, Rodolfo del Sole and Bernardo S. Mendoza, Phys. Rev. B 60, 2522-2527 (1999). citas página: 58 7.2.35 Visible-infrared sum and difference frequency generation at adsorbate covered Au, Bernardo S. Mendoza, W. Luis Mochán and J. Maytorena, Phys. Rev. B. 60, 14334-14340 (1999). citas página: 59 7.2.36 Optical second harmonic generation spectroscopy of boron-recunstructed Si(001), D. Lim, M. C. Downer, J. G. Ekerdt, N. Arzate, Bernardo S. Mendoza, V. Garvrilenko and R. Wu, Phys. Rev. Lett. 84, 3406-3409 (2000). citas página: 59 7.2.37 Disorder effects on second harmonic generation from one-dimensional arrays of polarizable units, J.Cruz-Mandujano and Bernardo S. Mendoza, Phys. Rev. B 62, 8438-8445 (2000). citas página: 60 7.2.38 Second harmonic generation from spherical particles, Vera L. Brudny, Bernardo S. Mendoza and W. Luis Mochán, Phys. Rev. B 62, 11152-11162 (2000). citas página: 60 16/74 7.2.39 Polarizable bond model for optical spectra of Si(100) reconstructed surfaces, N. Arzate and Bernardo S. Mendoza, Phys. Rev. B 63, 113303-1/4 (2001). citas página: 61 7.2.40 Microscopic study of surface second-harmonic generation form a clean Si(100) c(4 × 2) surface, N. Arzate and Bernardo S. Mendoza, Phys. Rev. B 63, 125303-1/14 (2001). 7.2.41 Ab-initio calculation of second-harmonic-generation at the clean Si(100) surface, Bernardo S. Mendoza, Maurizia Palummo, Giovanni Onida, and Rodolfo del Sole, Phys. Rev. B 63, 205406-1/6 (2001). citas página: 62 7.2.42 Second-harmonic-generation from single-domain Si(100) surfaces, J. Mejı́a and Bernardo S. Mendoza, Surface Science 487/1-3, 180-190 (2001). 7.2.43 Optical second harmonic spectroscopy of semiconductor surfaces: advances in microscopic understanding, M.C. Downer, B.S. Mendoza and V.I. Gavrilenko, Surface and Interface Analysis, Surf. Interface Anal. 31, 966-986 (2001). Artı́culo de revisión por invitación. citas página: 62 7.2.44 Optical second harmonic spectroscopy of silicon surfaces, interfaces and nanocrystals, M.C. Downer, Y. Jiang, D. Lim, L. Mantese, P.T. Wilson, B.S. Mendoza, and V.I. Gavrilenko, Phys. Stat. Sol. (a) 188, 1371-1381 (2001). citas página: 63 7.2.45 Polarizable-bond model for surface second-harmonic generation at Si(111):H (1× 1), J. E. Mejı́a and Bernardo S. Mendoza, Phys. Stat. Sol. (a) 188, 1393-1400 (2001). 7.2.46 Surface dc-electric field modified second-harmonic-generation at the B and Hcovered Si(100)2 × 1 surface, N. Arzate and Bernardo S. Mendoza, J. Opt. Technol. 69, 380-384 (2002); Opticheski Zhurnal-Optical Journal 69, 6-12 (2002). 7.2.47 Surface second harmonic generation from Si(111)(1 × 1)H: Theory versus Experiment, J. Mejı́a, Bernardo S. Mendoza, M. Palummo, G. Onida, R. Del Sole, S. Bergfel and W. Daum, Phys. Rev. B 66, 195329-1/5 (2002). citas página: 63 7.2.48 Model for the effects of surface disorder on reflectance anisotropy spectroscopy, Bernardo S. Mendoza, Norbert Esser and Wolfgang Richter, Phys. Rev. B 67, 165319-1,6 (2003). citas página: 63 17/74 7.2.49 Layer-by-layer analysis of surface reflectance anisotropy in semiconductors, C. Castillo, Bernardo S. Mendoza, W.G. Schmidt, P.H. Hahn, F. Bechstedt, Phys. Rev. B Rapid Communications 68, 041310 (2003). citas página: 63 7.2.50 Second harmonic generation in arrays of spherical particles, W.L. Mochán, J. Maytorena, Bernardo S. Mendoza, and V. Brudny, Phys. Rev. B 68, 085318-1,14 (2003). citas página: 63 7.2.51 Second-harmonic generation in the scattering of light by two-dimensional particles, Claudio I. Valencia, Eugenio R. Méndez and Bernardo .S. Mendoza, J. Opt. Soc. Am. B 20, 2150-2161 (2003). citas página: 64 7.2.52 Second harmonic generation from a collection of nanoparticles, Vera Brudny, W.L. Mochán, Jesús A. Maytorena, and Bernardo S. Mendoza, phys. stat. sol. (b) 240, 518-526 (2003). citas página: 64 7.2.53 Depth resolved nonlinear optical nanoscopy, W. Luis Mochán, Catalina López-Bastidas, Jesús A. Maytorena, Bernardo S. Mendoza, and Vera. L. Brudny, phys. stat. sol. (b) 240, 527-536 (2003). 7.2.54 Reflectance anisotropy for porphyrin octaester Langmuir-Schaefer films, C. Castillo, R.A. Vázquez-Nava, and Bernardo S. Mendoza, phys. stat. sol. (c) 0, 2971-2975 (2003). 7.2.55 Second-harmonic generation in the scattering of light by an infinite cylinder, C.I. Valencia, E.R. Méndez and B.S. Mendoza, J. Opt. Soc. Am. B 21, 36-44 (2004). citas página: 64 7.2.56 Layer-by-layer analysis of surface second harmonic generation at a simple surface, J. Mejı́a, C. Salazar y Bernardo S. Mendoza, Revista Mexicana de Fı́sica, 50 134-139 (2004). 7.2.57 Polarizable dipole models for reflectance anisotropy spectroscopy: a review, N. Arzate, B.S. Mendoza and R. Vázquez, J. Phys.: Condens. Matter 16 S4259-S4278 (2004). Artı́culo de revisión por invitación. citas página: 64 7.2.58 Spin-Orbit effects on reflectance anisotropy spectroscopy, R. Vázquez-Nava, Bernardo S. Mendoza, and C. Castillo, Phys. Rev. B 70, 165306 (2004). citas página: 65 7.2.59 Single- and enhanced two-beam second-harmonic generation from silicon nanocrystals by use of spatially inhomogeneous femtosecond pulses, P. Figliozzi, L. Sun, Y. Jiang, N. Matlis, B. Mattern, M.C. Downer, S.P. Withrow, C.W. White, W.L. Mochán, and B.S. Mendoza, Phys. Rev. Lett. 94, 047401 (2005). citas página: 65 18/74 7.2.60 Model for reflectance anisotropy spectra of molecular layered systems, Bernardo S. Mendoza and R.A. Vázquez-Nava, Phys. Rev. B 72, 035411 (2005). citas página: 65 7.2.61 Two-Beam Second-Harmonic Generation, Liangfeng Sun, Stefano Cattaneo, Pete Figliozzi, Yingying Jiang, Yong Qiang An, W. Luis Mochán, Bernardo S. Mendoza, Martti Kauranen, and Michael C. Downer, Special Issue: Optics in 2005, Optics and Photonics News, Nonlinear Optics, p. 30 December issue (2005). 7.2.62 Nonresonant quadrupolar second-harmonic generation in isotropic solids by use of two orthogonally polarized laser beams, L. Sun, P. Figliozzi, Y. Q. An, M. C. Downer, W. L. Mochán, and B. S. Mendoza , Optics Letters 30, 2287 (2005). citas página: 65 7.2.63 Theoretical model for adsorption of Sb on the GaAs(110) surface, B.S. Mendoza, N.Arzate, and R.A. Vázquez-Nava, phys. stat. sol. (c) 2, 4031–4036 (2005). 7.2.64 Second-harmonic spectroscopy of nano-interfaces, L. Sun, P.Figliozzi, Y.Jiang, M.C.Downer, W.L.Mochán, and B.S. Mendoza, phys. stat. sol. (c) 2, 4067–4071 (2005). citas página: 65 7.2.65 Spin-Orbit Effects on the Optical Anisotropy of Semiconductor Surfaces, R. A. Vázquez-Nava, B. S. Mendoza and N. Arzate, phys. stat. sol. (b) 242, 3022 (2005). 7.2.66 Layer-by-layer analysis of the linear optical response of clean and hydrogenated Si(100) surface, B. Mendoza, N. Arzate, F. Nastos and J. Sipe, Phys. Rev. B 74, 075318 (2006). 7.2.67 Second-harmonic and reflectance-anisotropy spectroscopy of vicinal Si(001)/SiO22 interfaces: Experiment and simplified microscopic model, Jinhee Kwon, M. C. Downer and B. S. Mendoza, Phys. Rev. B 73, 195330 (2006). citas página: 66 7.2.68 Second harmonic surface response of a composite, Bernardo S. Mendoza and W. Luis Mochán, Optical Materials 29, 1-5 (2006). 7.2.69 Full band structure LDA and k · p calculations of optical spin-injection, F. Nastos, J. Rioux, M. Strimas-Mackey, Bernardo S. Mendoza, and J. E. Sipe Phys. Rev. B, 76, 205113 (2007). citas página: 66 19/74 7.2.70 Theoretical study of the optical response of the adsorption of Sb on the GaAs(110) surface, Bernardo S. Mendoza, N. Arzate and R.A. Vázquez-Nava, Phys. Stat. Sol. (c) 8, 2604-2609 (2008). 7.3 Artı́culos en libros con arbitraje: 7.3.1 Interlevel plasmons in quasi-one dimensional structures, S.E. Ulloa, Y.C. Lee and B.S. Mendoza, Nanostructure Physics and Fabrication, M.A. Reed and W.P. Kirk, editors, Academic Press, Boston, 1989, p. 141. 7.4 Artı́culos de docencia con arbitraje: 7.4.1 Plasmons in Three, Two and One Dimension, B. S. Mendoza and M. del Castillo-Mussot, Revista Mexicana de Fı́sica 39, 640-652 (1993). 7.5 Memorias in extenso con arbitraje: 7.5.1 Longitudinal Gauge Theory of Second Harmonic Generation, B. S. Mendoza, EPIOPTICS-9 Proceedings of the 39th Course of the International School of Solid State Physics, Erice, Italy 20 - 26 July 2006 edited by Antonio Cricenti, ISBN 978-981-279-402-4, 981-279-402-6, World Scientific, p. 1-27 (2008). Platica Invitada. 7.5.2 Morphological study of organic molecular layers using a differential optical technique, Vazquez-Nava, R. A. and Mejia, J. E. and Mendoza, B. S., AIP Conference Proceedings 854 111-113 (2006). 7.5.3 Origin of optical anisotropy in reflectance anisotropy spectroscopy of semiconductor surfaces, Vazquez-Nava, RA and Arzate, N and Mendoza, BS, Proceedings of the Society of Photo-Optical Instrumentation Engineers (SPIE), 6046 Z460 (2006). 7.5.4 Nonlinear optical nanoscope with depth resolution, Mochan, WL and Lopez-Bastidas, C and Maytorena, JA and Mendoza, BS and Brudny, VL, RIAO/OPTILAS 2004, SPIE 5622 524-528 (2004). 20/74 7.5.5 Longitudinal Gauge Theory of Second Harmonic Generation at Semiconductor Surfaces, B. S. Mendoza, Epioptics-7, Proceedings of the 24th Course of the international School of Solid State Physics, Erice, Italy , Ed. A. Cricenti, World Scientific, ISBN 981-238-710-2, p. 52-61 (2004). Platica Invitada. 7.5.6 Polarizable bond model for reflectance anisotropy and second harmonic generation for Si(100) surfaces, N. Arzate and Bernardo S. Mendoza, Epioptics 2000, Proceedings of the 19th Course of the international School of Solid State Physics, Erice, Italy , Ed. A. Cricenti, World Scientific, ISBN 981-02-4771-0, p. 18-23 (2001). 7.5.7 Second harmonic spectroscopy of Si surfaces with H, Ge, and B adsorbates: experiment and theory, Downer, MC and Ekerdt, JG and Lim, D and Parkinson, P and Gavrilenko, VI and Wu, RQ and Arzate, N and Mendoza, BS, Nonlinear Optics: Materials, Fundamentals, and Applications (2000), ISBN 1-55752-646-X 46 p. 22-24. 7.5.8 Second Harmonic spectrsocopy of Si surfaces with H, Ge and B adsorbates: experiment and theory, M.C. Downer, J.G. Ekerdt, D. Lim, P. Parkinson, V.I. Gavrilenko, R.Q. Wu, N. Arzate and B. S. Mendoza, Nonlinear Optics: Materials, Fundamentals and Applications, Kauai-Lihue, Hawaii, August 7-11, 2000 Sponsored by Optical Society of America. Platica Invitada. 7.5.9 Hydrodynamic model of second-harmonic generation at metal surfaces, J.A. Maytorena, W.L. Mochán and B.S. Mendoza, Second Iberoamerican Meeting on Optics SPIE 2730, 376-388 (1995). Platica Invitada. 7.5.10 Exactly solvable model of surface second harmonic generation, B.S. Mendoza and W.L. Mochán, IEEE/LEOS Nonlinear Optics IEEE Catalog Num. 94CH3370-4, 319 (1994). 7.5.11 Second harmonic generation at conductor surfaces with continuous profiles, W.L. Mochán, J. Maytorena and B.S. Mendoza, IEEE/LEOS Nonlinear Optics IEEE Catalog Num. 94CH3370-4, 318 (1994). 21/74 7.5.12 Giant Local Field Enhancement in Second Harmonic Generation in a Two Dimensional Array of Quantum Dots, Bernardo S. Mendoza, Frontiers in Information Optics, Kyoto, Japan, 4b2-1 (1994). 7.5.13 Generación del Segundo Armónico y Procesos Opticos No-Lineales en Arreglos Periódicos de Pozos Cuánticos, B.S. Mendoza y A. Guerrero, Proceedings, 1a Reunion Iberoamericana de Optica Barcelona, España, 112113 (1992). 7.5.14 Generación del Segundo Armónico en Superficies Cristalinas, B.S. Mendoza, 1er Coloquio de Fı́sica de Superficies, Universidad de Sonora, 77-93 (1991). 7.6 Artı́culos interdiciplinarios con arbitraje 7.6.1 Friction coefficients of human submandibular sublingual and parotid saliva, A. Aguirre, B.S. Mendoza, N.H. Hatton and M.J. Levin, Journal of Dental Research 67, 992 (1988). citas página: 66 7.6.2 Lubrication of selected salivary molecules and artificial salivas, A. Aguirre, B.S. Mendoza, M.S. Reddy, F.A. Scannapieco and M.J. Levine, Dysphagia 4, 95-100 (1989). citas página: 66 7.6.3 In vitro characterization of human salivary lubrication, A. Aguirre, B.S. Mendoza, M.J. Levin, M.N. Hatton and W. H. Douglas, Archives of Oral Biology 34, 675-677 (1989). citas página: 66 7.7 Capı́tulos en libros: 7.7.1 Polarizable dipole models for linear and non linear spectroscopy: a review, B.S. Mendoza, J.E. Mejia, N. Arzate and R.A. Vázquez-Nava, Some Topics in Modern Optics: Contribution to the World in CIO’s 25 years of life, p. 225-282, Rinton Press (USA), ISBN 1-58949-057-6, 2008. 7.7.2 Polarizable dipole models for linear and non-linear optical surface spectroscopy, B.S. Mendoza, N. Arzate, R. Vázquez-Nava, J. Mejı́a y W.L. Mochán Optical Techniques for Surface Optics, Recent Research in Photonics, Ed. Research Signpost, ISBN: 978-81-308-0348-7 (2008), Chapter 1. 7.7.3 Linear Optical Response of Nanotubes, N. Arzate, R.A. Vázquez-Nava, J.E. Mejı́a, C.M. González and B.S. Mendoza Optical Techniques for Surface Optics, Recent Research in Photonics, Ed. Research Signpost, ISBN: 978-81-308-0348-7 (2008), Chapter 3. 22/74 7.8 Artı́culos enviados con arbitraje: 7.8.1 Effective dielectric response of metamaterials, Guillermo P. Ortiz, B.E. Martı́nez-Zérega, Bernardo S. Mendoza, and W. Luis Mochán, enviado a Phys. Rev. B. # BA11226. 7.9 Artı́culos en preparación con arbitraje: 7.9.1 Surface second harmonic generation at clean and H covered Si(111) 7 × 7, J. Mejı́a, Bernardo S. Mendoza and K. Pedersen, por ser enviado a Phys. Rev. B. 7.9.2 Effects of Spin-Orbit coupling in CdTe, R. Vázquez-Nava, Norberto Arzate y Bernardo S. Mendoza, por ser enviado a Phys. Rev. B rapid communications. 7.9.3 Stress modulation of the degree of spin polarization on bulk semiconductors, C. Salazar, J. Cabellos, and B. Mendoza, por ser enviado a Phys. Rev. B. rapid communications. 7.9.4 Optical coherent current control at surfaces: theory of injection current, J. Cabellos, Bernardo S. Mendoza, F. Nastos, A. Shkrebtii and J.E. Sipe, por ser enviado a Phys. Rev. B. 7.9.5 One-photon spin injection in semiconductor surfaces, J. Cabellos, B. Mendoza, F. Nastos, T. Rangel, N. Arzate, y J. Sipe, por ser enviado a Phys. Rev. B. 7.9.6 r · E versus v · A calculations of second harmonic generation for semiconductors, J. Cabellos, M. Escobar, B. Mendoza, F. Nastos, y J. Sipe, por ser enviado a Phys. Rev. B. 7.9.7 Sum and difference frequency generation from random surfaces, M. Leyva-Lucero, Bernardo S. Mendoza, and E. Méndez, por ser enviado a J. Opt. Soc. Am B. 7.9.8 Haydock method for the effective optical response of composites, B.E. Martı́nez-Zérega, H. Sánchez, G. Ortiz, Bernardo S. Mendoza, and W.L Mochán, por ser enviado a Optics Express. 7.9.9 Haydock approach vs a numerical method for the effective optical response of two-dimensional metamaterials, H. Sánchez, E. Cortes, G. Ortiz, Bernardo S. Mendoza, and W.L. Mochán, por ser enviado a Optics Express. 7.9.10 Optical shift- and injection-current response of boron nitride nanotubes, N. Arzate, F. Nastos, R.A. Váazquez-Nava, C. Miguel González, B.S. Mendoza, and John Sipe, por ser enviado a Phys. Rev. B. 23/74 8 Editor Cientı́fico 8.1 physica status solidi (c) 0 Num. 8 (2003), Guest Editor, 5th International Conference on Optics of Surfaces and Interfaces, Wiley-VCH, Berlin, ISBN 3-527-40494-5. 9 Programas de Computo Registrados 9.1 TINIBA: Programas para el Cálculo en Paralelo de Respuestas Ópticas en Semiconductores Usando un Cluster de Computo, Bernardo Mendoza Santoyo, José Luis Cabellos Quiroz, y Tonatiuh Rangel Gordillo Instituto Nacional de Derechos de Autor, en registro. 10 Comités Cientı́ficos Internacionales 10.1 Optics of Surfaces and Interfaces OSI, Comité Cientı́fico internacional encargado de la investigacón de la óptica de superficies, su proliferación y divulgación a través de un Congreso Internacional organizado cada 2 años. 10.2 EPIOPTICS Comité Cientı́fico internacional encargado de la investigacón de la óptica de superficies, su proliferación, divulgación y colaboración entre la comunidad cientı́fica internacional. En particular coordina una Escuela de Verano organizada cada 2 años en el Centro Ettore Majorana en Erice, Sicilia, Italia. 11 Comités Evaluadores 11.1 Comité Externo de Evaluación del CICESE. Comité de evaluación cientı́fica y académica del Centro de Investigación Cientı́fica y de Educación Superior de Ensenada, CICESE. Invitado por el CONACyT. 24/74 12 Organización de Congresos 12.1 Optics of Surfaces and Interfaces OSI-V, Chairman, Centro de Investigaciones en Optica, León, GTO, México, 26-30 Mayo, 2003. 12.2 XLV Congreso Nacional de Fı́sica Comite de organización local León, GTO, México Octubre 2002. 13 Reuniones de Trabajo 13.1 International School of Solid State Physics, 9th Workshop: EPIOPTICS 4, Ettore Majorana Center for Scientific Culture, Erice, Italy. June 9-14 (1996). Local-field effect in the SHG spectra of Si Surfaces. Presentación Oral: 13.2 International School of Solid State Physics, 14th Workshop:EPIOPTICS 5, Ettore Majorana Center for Scientific Culture, Erice, Italy. June 17-22 (1998). Microscopic theory of second-harmonic-generation at the Si(100) surface Presentación Oral: 13.3 Workshop on Surface and Interface Optics: SIO’99, Saint-Maxime, France. 4-9 May 1999. DC-electric-field modified second-harmonic-generation at the Si(100) surface, Presentación Oral: 13.4 Workshop on Recent Advances on Light Scattering and Related Phenomena, Ensenada, México. May 27-28, 1999. DC-electric-field modified second-harmonic-generation at the Si(100) surface, Platica Invitada. 14 Invitación a Cursos Cortos 14.1 International School of Solid State Physics, 43th Course: EPIOPTICS 10-2008, Ettore Majorana Center for Scientific Culture, Erice, Italy. June (2008). Curso: Optical Spin Injection on Semiconductor Surfaces. 25/74 14.2 Spring School: Nonlinear and Multiscale Photonics, Binational Consortium of Optics, Tucson, Arizona, Noviembre, 2006 Curso: Calculation of the effective dielectric response of metamaterials. 14.3 International School of Solid State Physics, 20th Course: EPIOPTICS 2006, Ettore Majorana Center for Scientific Culture, Erice, Italy. July (2006). Curso: Longitudinal Gauge Theory of Second Harmonic Generation. 14.4 Spring School: Nonlinear and Multiscale Photonics, Binational Consortium of Optics, Tucson, Arizona, April 1-3, 2005 Curso: Calculation of second harmonic generation at surfaces. 14.5 International School of Solid State Physics, 20th Course: EPIOPTICS 2004, Ettore Majorana Center for Scientific Culture, Erice, Italy. July (2004). Curso: Longitudinal Gauge Theory of Second Harmonic Generation at Semiconductor Surfaces. 14.6 International School of Solid State Physics, 20th Course: EPIOPTICS 2002, Ettore Majorana Center for Scientific Culture, Erice, Italy. July 21-25 (2002). Curso: Theory on surface second harmonic generation. 14.7 International School of Solid State Physics, 19th Course: EPIOPTICS 2000, Ettore Majorana Center for Scientific Culture, Erice, Italy. July 19-25 (2000). Curso: Theory on surface second harmonic generation. 15 Estancias de Investigación 15.1 Departamento de Fı́sica, Universidad de Toronto, Septiembre de 2004 a Agosto de 2005, con el Profesor John Sipe. Año Sabático. 15.2 Departamento de Fı́sica, Universidad de Texas en Austin, Diciembre 2003, con el Profesor Michael Downer. 15.3 Departamento de Fı́sica, Universidad Tecnica de Berlin, Junio-Julio 2003, con el Profesor Wolfgang Richter y Norbert Esser. 15.4 Departamento de Fı́sica, Universidad Tecnica de Berlin, 26/74 15.5 15.6 15.7 15.8 15.9 16 Enero-Febrero 2002, con el Profesor Wolfgang Richter. Departamento de Fı́sica, Universidad de Roma II, Febrero del 2001, con el Profesor Rodolfo Del Sole. Departamento de Fı́sica, Universidad de Roma II, Julio de 2000, con el Profesor Rodolfo del Sole. Departamento de Fı́sica, Universidad de Texas en Austin, Julio-Septiembre de 1999, con el Profesor Michael Downer. Departamento de Fı́sica, Universidad de Roma II, Septiembre de 1997 a Agosto de 1998, con el Profesor Rodolfo del Sole. Año Sabático. Departamento de Fı́sica, Universidad de Roma II, Noviembre de 1996 a Diciembre de 1996, con el Profesor Rodolfo del Sole. Formación de Personal Académico 16.1 Doctorado 16.1.1 Fı́s. Norberto Arzate Plata: Second Harmonic Generation at Crystaline Semiconductor Surfaces. CIO. Doctorado. Noviembre del 2000. S.N.I. Nivel I 22296. 16.1.2 M. en C. Javier Cruz Mandujano: Generación del segundo armónico en cadenas dipolares desordenadas. CIO. Doctorado. Diciembre del 2000. S.N.I. Nivel 1 15291. 16.1.3 Fı́s. Jorge Enrique Mejı́a Sánchez: Second Harmonic Generation as a Surface Probe. CIO. Doctorado. Diciembre del 2001. S.N.I. Nivel I 26430 16.1.4 M. en C. César Castillo Quevedo: Reflectance Anisotropy Spectroscopy: a Tool for Surface Studies. CIO. Doctorado. Diciembre del 2003. S.N.I. candidato 35656. 27/74 16.2 Maestrı́a 16.2.1 Fis. Eunice Jonguitud Isurrieta: Respuesta No-Lineal de una Cadena Desordenada de Esferas Polarizables. CIO. Maestria. Diciembre de 1994. 16.2.2 Fı́s. Ariel Sánchez: Respuesta No-Lineal de un Disco Cuántico. CIO. Maestria. Diciembre de 1994. 16.2.3 Fı́s. Alfonso Guerrero: Generación del Segundo Armónico en un sistema de Pozos Cuánticos. UNAM. Maestria. Marzo de 1995. 16.2.4 Ing. Tonatiuh Rangel Gordillo: Optical injection of spin population and spin current in semiconductor surfaces. CIO. Maestria, diciembre 2006. 16.2.5 Marco Antonio Escobar Acevedo. Length vs. transversal gauge calculations for nonlinear optics CIO. Maestria, septiembre 2007. 16.2.6 Juan Cuauhtémoc Salazar González. Stress Modulation of the Degree of Spin Polarization on Bulk Semiconductors CIO. Maestria, Diciembre 2008. 16.3 Licenciatura 16.3.1 Fı́s. Juan Cuauhtemoc Salazar González: Análisis por capas de la generación de segundo armónico en superficies semiconductoras. Universidad de Guadalajara, Licenciatura, agosto 2006. 16.4 Tesistas En Proceso 16.4.1 M. en C. José Luis Cabellos Quiroz. CIO. Doctorado, 9o semestre. Fecha de Graduación: Verano 2009. 16.4.2 M. en C. Juan Cuauhtemoc Salazar González: CIO. Doctorado, 1er semestre. 16.4.3 M. en C. Luis Adán Martı́nez Jiménez. CIO. Doctorado, 3er semestre. Ayudante de Investigador. 16.4.4 Ernesto Carlos Cortés Morales. Instituto de Fı́sica de la Universidad de Guanajuato. Licenciatura, 1er semestre. Beca SNI de Licenciatura. 28/74 17 Posdoctorantes 17.1 Dr. Héctor Sánchez Hernández. Cálculo de propiedades ópticas de nanometamateriales. Marzo 2008 a Febrero 2009. 18 Sinodal de Tesis 18.1 Claudia Elena Ferreiro Córdova Simulación molecular de esferocilindros duros con momento bipolar de orientación variable Tesis de Licenciatura en Ingenieria Fı́sica. Instituto de Fı́sica, Universidad de Guanajuato. Junio 2008. 18.2 Ing. Rigoberto Castro Beltran Técinca Z-scann para la medición de coeficientes ópticos no lineales en materiales organicos Tesis de Maestrı́a. Centro de Investigaciones en Optica, Diciembre del 2007. 18.3 M. en C. Edgar Reyes Ayona Homogeneización de cristales fotónicos con componentes magnéticas anisotrópicas y dispersivas Tesis de Doctorado. Benemérita Universidad Autónoma de Puebla, Mayo del 2006. 18.4 Fı́s. Maximiliano Galán González. Detección de Planetas Extra-Solares con un Interferómetro de Desplazamiento Rotacional: Condiciones. Tesis de Maestrı́a. Centro de Investigaciones en Optica, Agsoto del 2005. 18.5 Ing. Raúl Alfonso Vázquez Nava Transiciones opticas y modos colectivos de semiconductores de baja dimensionalidad, Universidad Autónoma del Estado de Morelos, Noviembre de 1999. 19 Seminarios Cientı́ficos 19.1 Slender acoustic plasmons at finite temperature. 19.1.1 State University of New York at Buffalo, Physics Dep. 6 de Oct. 1987. 19.2 Possible high Tc superconductivity in thin wires. 19.2.1 State University of New York at Buffalo, Physics Dep. 6 de Dic. 1988. 29/74 19.3 A possible mechanism for superconductivity in slender wires. 19.3.1 Indiana University, Physics Department, 2 de Marzo, 1990 19.3.2 Ohio University, Physics Department, 8 de Feb. 1990 19.4 Plasmones en sistemas de dimensión reducida. 19.4.1 UAM-I, D.F., 24 de Enero, 1992. 19.4.2 UNAM, Instituto de Fı́sica-Ensenada, 20 de Mayo, 1991. 19.4.3 UNAM, Instituto de Fı́sica-D.F., 11 de Enero, 1991. 19.5 Second harmonic generation from a quantum dot array. 19.5.1 THOMSON-CSF, Laboratorie Central de Recherches, Orasy Francia,14/09/92. 19.5.2 Fı́sica de Materia Condensada, Univesidad Autónoma de Madrid, 28/09/92. 19.6 Un modelo Simple para la Generación del Segundo Armónico. 19.6.1 19.6.2 19.6.3 19.6.4 Instituto de Fı́sica, UNAM, Cuernavaca. 14 de Mayo de 1992 Instituto de Fı́sica, UNAM, Ensenada. 16 de Octubre de 1992 CINVESTAV, México D.F. 21 de Abril de 1993 Instituto de Fı́sica, Universidad de Gunajuato, 18 de Junio de 1993. 19.7 Un Modelo Simple para la Generación del Segundo Armónico en Si y Ge 19.7.1 Instituto de Fı́sica, UASLP, 17 de Noviembre de 1993 19.8 Local Field Effect on SHG from Si 19.8.1 Non-Linear Optics Department, Moscow State University, 13 de Enero de 1996. 19.8.2 Physics Department, University of Nijmegen, The Netherlands, 5 de Agosto de 1996. 19.9 Microscopic model of SHG at Si(100) surfaces 19.9.1 Max-Plank Institute for Quantum Optics, Garching, Germany, September 17, 1998. 19.9.2 Department of Physics, U. of Texas at Austin, December 4, 1998. 19.9.3 Department of Physics, U. of Columbia, New York, November 10, 1999. 19.10 Un modelo microscópico para la generación del segundo armónico en superficies de semiconductores 19.10.1 CICESE, Dpto. de Optica, 15 de Noviembre del 2000. 19.10.2 I. de Fı́sica, UASLP, 27 de Febrero del 2001. 19.11 Espectroscopı́a de reflectancia anisotrópica y efectos de desorden en superficies 19.11.1 CCF, UNAM, Cuernavaca, 16 de octubre del 2002. 30/74 19.12 Layer-by-layer analysis of spectroscopic optical surface probes for semiconductors 19.12.1 19.12.2 19.12.3 19.12.4 Universidad Universidad Universidad Universidad Catolica de Nijmegen, Holanda, 16 de junio del 2003. Técnica de Berlin, Alemania, 2 de julio del 2003. de Columbia, Nueva York, 12 de septiembre del 2003. de Texas en Austin, 5 de diciembre del 2003. 19.13 Second-harmonic generation in nanoparticles 19.13.1 Universidad Friedrich-Schiller, Jena, Alemania, 14 de julio del 2003. 19.13.2 Universidad de Texas en Austin, 11 de diciembre del 2003. 19.14 Espintrónica asistida por Fotones 19.14.1 Universidad de Sinaloa, Culiacan, noviembre 2007. 19.14.2 CIO, SPIE Student Chapter, abril 2008. 20 Artı́culos de Divulgación 20.1 Tocara su CD algún dı́a realmente los Blues, Periódico A.M. de León, Gto. 21 de Marzo de 1999. 20.2 El Mundo Paranormal Visto por un Mago, Périodico AM, León GTO. 19 de Marzo del 2000. 20.3 La óptica no-lineal en el CIO, Noticio, Octubre del 2000. 20.4 Ciencia Básica y Tecnologı́a: Posicionador Global, Périodico AM, León GTO., 8 de Julio del 2001. 20.5 Cluster de Cómputo en el CIO, Périodico A.M., León GTO., diciembre del 2003. 20.6 ¡Las cosas no son como parecen! Périodico A.M., León GTO., diciembre del 2004. 20.7 ¿Que es la Espintronica? Périodico A.M., León GTO., marzo 2007. 20.8 Software Libre en el CIO: TINIBA un ejemplo a seguir. Périodico A.M., León GTO., enviado 2008. 31/74 21 Seminarios de Divulgación 21.1 El Cientı́fico y los Laseres Instituto Lux, León, 27 de Abril de 1994. 21.2 ¿ Que es la Luz ? Museo Explora, León, Gto. Enero 1995. 21.3 Cálculo de Primeros Principios de las Propiedades Opticas de Materiales, Taller de Ciencias para Jóvenes, CIMAT, GTO., 25 de Julio del 2001. Práctica. 21.4 Optica No-lineal en el CIO, Entrevista en Televisa Bajı́o, Lunes 5 de noviembre, 2002. 21.5 Sistema Posicionador Global: Relatividad General de A. Einstein al alcanze de todos, Centro Universitario de Lagos, Universidad de Guadalajara, Diciembre 2 del 2005. 21.6 Teorema: Diálogos con la naturaleza, diálogos con la ciencia, Entrevista de Radio, Centro Universitario de Lagos, Universidad de Guadalajara, Diciembre 2 del 2005. 21.7 Sistema Posicionador Global: Relatividad General de A. Einstein al alcanze de todos, Preparatoria Oficial de Silao, 24 de abril (2006). 21.8 Optoespintrónica, y Optica no-lineal de nanopartı́culas, Centro Universitario de Lagos, Universidad de Guadalajara, Julio 13 del 2006. 21.9 Espı́ntronica asistida por fotones, U. A. de Sinaloa, XXV aniversario de la fundación de la Escuela de Ciencias Fı́sico-Matemáticas, 13 de noviembre de 2007. 21.10 Sistema Posicionador Global: Relatividad General de A. Einstein al alcanze de todos, Preparatoria Oficial de Silao, 11 de abril de 2008. 21.11 Espı́ntronica asistida por fotones, U Veracruzana, V encuentro Xalapeño de Fı́sica, 9 de mayo de 2008. 21.12 El quehacer cientı́fico, CIO, octubre 15 del 2008. 22 Congresos Nacionales 22.1 Generación del Segundo Armónico en Superficies Cristalinas B.S. Mendoza, 1er Coloquio de Fı́sica de Superficie, Universidad de Sonora, mayo de 1991. 32/74 22.2 Un modelo simple para la generación del segundo armónico B.S. Mendoza, A. Guerreo y E. Jonguitud, 3a Reunión de Trabajo sobre Espectroscopias Opticas, CINVESTAV, México, D.F. julio de 1991. 22.3 Un modelo simple para la generación del segundo armónico B.S. Mendoza, XXXV Congreso Nacional de Fı́sica, Puebla, octubre 1992. 22.4 Generación del segundo armónico en medios dipolares no periódicos E. Jonguitud y B.S. Mendoza, XXXV Congreso Nacional de Fı́sica, Puebla, octubre 1992. 22.5 Generación del segundo armónico por un sistema de pozos cuánticos A. Guerreo y B.S. Mendoza, XXXV Congreso Nacional de Fı́sica, Puebla, octubre 1992. 22.6 Generación del segundo armónico en un gas confinado de electrones A. Sánchez y B. Mendoza, XXXVI Congreso Nacional de Fı́sica, Acapulco, octubre 1993. 22.7 Generación del segundo armónico en arreglos dipolares desordenados E. Jonguitud y B. Mendoza, XXXVI Congreso Nacional de Fı́sica, Acapulco, octubre 1993. 22.8 Generación del segundo armónico en Si y Ge B. Mendoza y L. Mochán, XXXVI Congreso Nacional de Fı́sica, Acapulco, octubre 1993. 22.9 Modelo hidrodinámico para la respuesta no-lineal en superficies metálicas J. Maytorena, L. Mochán y B. Mendoza, XXXVI Congreso Nacional de Fı́sica, Acapulco, octubre 1993. 22.10 Modelo de enlaces polarizables para los coeficientes electro-ópticos lineales J. Cruz y B. Mendoza, XXXVIII Congreso Nacional de Fı́sica, Zacatecas, octubre 1995. 22.11 Second harmonic-generation from disordered linear chains of polarizable spheres J. Cruz, E. Jonguitud y B. Mendoza, XXXIX Congreso Nacional de Fı́sica, Oaxaca, octubre 1996. 22.12 Susceptibilidades no-lineales para sistemas electronicos confinados N. Arzate, J. Mejı́a y B. Mendoza, XXXIX Congreso Nacional de Fı́sica, Oaxaca, octubre 1996. 22.13 Exactly solvable model of surface sum frequency generation B. Mendoza, L. Mochán, J. Maytorena y J. Cruz, XXXIX Congreso Nacional de Fı́sica, Oaxaca, octubre 1996. 33/74 22.14 Generación óptica de suma y diferencia de frecuencias en superficies metálicas J. Maytorena, L. Mochán y B. Mendoza, XXXIX Congreso Nacional de Fı́sica, Oaxaca, octubre 1996. 22.15 Generación de Segundo Armónico en Superficies Si(100):H N. Arzate, J. E. Mejı́a y B. Mendoza, XL Congreso Nacional de Fı́sica, Monterrey, octubre 1997. 22.16 Susceptibilidad no-lineal de segundo orden para un sistema electrónico con geometrı́a elipsoidal N. Arzate, J. E. Mejı́a y B. Mendoza, XLI Congreso Nacional de Fı́sica, San Luis Potosı́., octubre 1998. 22.17 Generación de suma y diferencia de frecuencias en superficies de Si en base al modelo de enlaces polarizables N. Arzate and Bernardo S. Mendoza, XLI Congreso Nacional de Fı́sica, San Luis Potosı́, octubre 1998. 22.18 Cálculo de la anisotropı́a óptica y generación de segundo armónico de superficies reconstruidas de Si(100) en base al modelo de enlaces polarizables N. Arzate y Bernardo S. Mendoza, XLIII Congreso Nacional de Fı́sica, Puebla, Puebla, noviembre 2000. 22.19 Efectos microscópicos de la susceptibilidad en la generación de segundo armónico en superficies N. Arzate y Bernardo S. Mendoza, XLIII Congreso Nacional de Fı́sica, Puebla, Puebla, noviembre 2000. 22.20 Cálculo microscópico para la GSA en superficies de H-Si(111)1 × 1 J. Mejı́a y B. Mendoza, XLIII Congreso Nacional de Fı́sica, Puebla, Puebla, noviembre 2000. 22.21 Generación de segundo armónico en superficies de Si(100) de un solo dominio J. E. Mejı́a, Bernardo S. Mendoza, XLIV Congreso Nacional de Fı́sica, Morelia, Michoacan, noviembre 2001. 22.22 Calculos Teoricos para la generación de segundo armónico vs experimentos:Si(111):H (1 × 1) como caso particular J. Mejı́a, B.S. Mendoza, M. Palummo, G. Onida, R. Del Sole, S. Bergfeld and W. Daum, XLIV Congreso Nacional de Fı́sica, Morelia, Michoacan, noviembre 2001. 22.23 Generación de segundo armónico por medios compuestos W.L. Mochán, J. Maytorena, V. Brudny, B.S. Mendoza, XLV Congreso Nacional de Fı́sica, León, Guanajuato, octubre, 2002. 22.24 Generación de segundo armónico en superficies de Si(111) 7 × 7 J. Mejı́a y B.S. Mendoza, XLV Congreso Nacional de Fı́sica, León, Guanajuato, octubre, 2002. 34/74 22.25 Análisis por planos de la generación de segundo armónico de una superficie de Si(111): H (1 × 1) J. Mejı́a, C. Salazar y B.S. Mendoza, XLV Congreso Nacional de Fı́sica, León, Guanajuato, octubre, 2002. 22.26 Espectrsocópias ópticas de superfice B.S. Mendoza, XLV Congreso Nacional de Fı́sica, León, Guanajuato, octubre, 2002. Platica Invitada. 22.27 Reflectance anisotropy of porphyrin octaester Langmuir-Schaefer films C. Castillo, R. Vázquez, and B.S. Mendoza, XLVI Congreso Nacional de Fı́sica, Mérdia, Yucatán, octubre, 2003. 22.28 Generación del segundo armónico en una pelı́cula delgada inducida por un haz finito con polarización y estructura transversal arbitrarias J.A. Maytorena, W.L. Mochán, B.S. Mendoza, and V.L. Brudny, XLVI Congreso Nacional de Fı́sica, Mérdia, Yucatán, octubre, 2003. 22.29 Respuesta óptica no-lineal de la corriente en superficies de semiconductores N. Arzate, B.S. Mendoza, F. Nastos, and J.E. Sipe, XLVI Congreso Nacional de Fı́sica, Mérdia, Yucatán, octubre, 2003. 22.30 Nanoscopio óptico no-lineal W.L. Mochán, J.A. Maytorena, C. López, B.S. Mendoza, V.L. Brudny, XLVI Congreso Nacional de Fı́sica, Mérdia, Yucatán, octubre, 2003. 1er Lugar. 22.31 Efecto de acoplamiento spin-orbita en los espectros de reflectancia anisotrópica de superficies semiconductoras R.A. Vázquez, C. Castillo y B.S. Mendoza, XLVI Congreso Nacional de Fı́sica, Mérdia, Yucatán, octubre, 2003. 22.32 Mesa Redonda: Espectroscopı́as no lineales B. Mendoza, XLVI Congreso Nacional de Fı́sica, Mérdia, Yucatán, octubre, 2003. Panelista Invitado. 22.33 Cálculo del espectro de reflectancia diferencial de la superficie de Si(100) con adsorción de Hidrógeno N. Arzate, B.S. Mendoza, F. Nastos and J.E Sipe XLVII Congreso Nacional de Fı́sica, Hermosillo, Sonora, octubre del 2004. 22.34 Reflectance anisotropy spectroscopy of semiconductor surfaces including spin-orbit coupling R. A. Vázquez-Nava, B. S. Mendoza and C. Castillo, XLVII Congreso Nacional de Fı́sica, Hermosillo, Sonora, octubre del 2004. 35/74 22.35 Reflectance anisotropy for porphyrin octaester Langmuir-Schaefer films C. Castillo, R. A. Vázquez-Nava y B. S. Mendoza, XLVII Congreso Nacional de Fı́sica, Hermosillo, Sonora, octubre del 2004. 22.36 Generación de segundo armónico en superficies de Si(111) 7 × 7 J. Mejı́a y B. S. Mendoza, XLVII Congreso Nacional de Fı́sica, Hermosillo, Sonora, octubre del 2004. 22.37 Theoretical study of the optical anisotropy response of molecular layered systems R. A. Vázquez-Nava and B. S. Mendoza, Simposium de Investigación y Desarrollo tecnológico, Centro de Investigaciones en Optica, abril 2005. 22.38 Origin of the optical anisotropy in reflectance anisotropy spectroscopy of semiconductor surfaces R. A. Vázquez-Nava and B. S. Mendoza and N. Arzate, Simposium de Investigación y Desarrollo tecnológico, Centro de Investigaciones en Optica, abril 2005. 22.39 Non-linear Optical Spectroscopy of the Silicon Surfaces J. E. Mejı́a y B. S. Mendoza, Simposio de Investigación y Desarrollo Tecnológico, Centro de Investigaciones en Optica, abril 2005. 22.40 Non-linear Optical Spectroscopy of the Silicon Surfaces J. E. Mejia and Bernardo S. Mendoza, V Simposio La Optica en la Industria, Santiago de Queretaro, Queretaro, septiembre 2005. 22.41 Inyección óptica de spı́n en superficiess de semiconductores N. Arzate, B.S. Mendoza, J.L. Cabellos, F. Nastos and J.E. Sipe, V Simposium la Óptica en la Industria, Querétaro, Querétaro, septiembre 2005. 22.42 Theoretical models for optical anisotropy response of molecular layered systems R.A. Vázquez-Nava y B. S. Mendoza, XLVIII Congreso Nacional de Fı́sica, Guadalajara, Jalisco, octubre del 2005. 22.43 Respuesta óptica no lineal de la corriente en capas de semiconductores C.M. González, N. Arzate, B.S. Mendoza, F. Nastos, and J.E. Sipe, XLVIII Congreso Nacional de Fı́sica, Guadalajara, Jalisco, octubre del 2005. 22.44 Band structure calculations of the surface linear optical response of the clean and hydrogenated Si(100) surface B.S. Mendoza, N. Arzate, F. Nastos and J.E. Sipe, XLVIII Congreso Nacional de Fı́sica, Guadalajara, Jalisco, octubre del 2005. Platica Invitada 36/74 22.45 Propiedades Electrónicas de la Superficie Si(111) J. E. Mejı́a, Omar Contreras y B. S. Mendoza, XLVIII Congreso Nacional de Fı́sica, Guadalajara, Jalisco, octubre 2005. 22.46 Cálculo microscópico por capas atómicas para la respuesta no lineal de superficies de Si(111) J. E. Mejı́a, Guadalupe J. Serratos y B. S. Mendoza, XLVIII Congreso Nacional de Fı́sica, Guadalajara, Jalisco, octubre 2005. 22.47 Espitrónica Asistida por Fotones: Cálculos en Clusters de Alto Rendimiento B. Mendoza, Simposio de Supercómputo Noroeste 2006, Hermosillo, febrero 2006. Platica Invitada 22.48 Contribucion del pseudopotencial no local a los elementos de matriz del operador momento J. Luis Cabellos, Bernardo Mendoza, Fred Nastos, y John Sipe, XLIX Congreso Nacional De Fı́sica. SLP, octubre 2006. 22.49 Derivacion Analitica del Analisis por Planos de la Generacion de Segundo Armonico en Supercies Semiconductoras Cuauhtemoc Salazar y Bernardo Mendoza, XLIX Congreso Nacional De Fı́sica. SLP, octubre 2006. 22.50 Optical spin injection on semiconductor surfaces J.L. Cabellos, B. Mendoza, T. Rangel, N. Arzate, F. Nastos, y J. Sipe, L Congreso Nacional De Fı́sica. Boca del Rio, octubre 2007. 22.51 Optical injection current on semiconductor surfaces J.L. Cabellos, B. Mendoza, F. Nastos, J. Sipe, y A. Shkrebtii L Congreso Nacional De Fı́sica. Boca del Rio, octubre 2007. 22.52 Optical properties of 2D arrays of metallo-dielectric metamaterials B. Martı́nez, G. Ortiz, y B. Mendoza, L Congreso Nacional De Fı́sica. Boca del Rio, octubre 2007. 22.53 Photon assisted spintronics B. Mendoza, Vértice 2008, ITESM, Campus León, febrero 27, 2008. Platica Invitada. 22.54 Optical spin injection on semiconductor surfaces B. Mendoza, V Encuentro Xalapeño de Fı́sica, Xalapa, Veracruz, Mayo 10, 2008. Platica Invitada. 22.55 Longitudinal versus transversal gauge theory of second harmonic generation for semiconductors J. Cabellos, M. Escobar, B. Mendoza, F. Nastos y J. Sipe, LI Congreso Nacional De Fı́sica. Zacatecas, octubre 2008. 22.56 Optical Shift Current Injection on Semiconductor Surfaces J. Cabellos, B. Mendoza, N. Arzate, F. Nastos y J. Sipe, LI Congreso Nacional De Fı́sica. Zacatecas, octubre 2008. 37/74 22.57 Optical properties of nano-sized metamaterials B. Martı́nez, G. Ortiz, H. Sánchez, B. Mendoza, W.L. Mochán. LI Congreso Nacional De Fı́sica. Zacatecas, octubre 2008. 22.58 Software development for numerical calculation of optical spin injection on stressed bulk semiconductors C. Salazar, J. Cabellos y B. Mendoza, LI Congreso Nacional De Fı́sica. Zacatecas, octubre 2008. 23 Congresos Internacionales 23.1 Slender acoustic plasmons at finite T B.S. Mendoza and Y.C. Lee, APS March Meeting, New York, Bull. Am. Phys. Soc. 32, 627 (1987). 23.2 A multi-mode theory of high temperature superconductivity Y.C. Lee, B.S. Mendoza and D. Chuu, APS March Meeting, New Orleans. Bull. Am. Phys. Soc. 33, 733 (1988). 23.3 A possible superconducting mechanism by acoustic plasmons in quasi-1D electron systems Y.C. Lee, B.S. Mendoza and S. Ulloa, APS March Meeting, New Orleans. Bull.Am.Phys.Soc. 33, 773 (1988). 23.4 A possible superconducting mechanism for high Tc in quasi-one dimensional multi-wire structures B.S. Mendoza and Y.C. Lee, APS March Meeting, St. Louis. Bull. Am. Phys. Soc. 34, 511 (1989). 23.5 A possible superconducting mechanism for high Tc in quasi-one dimensional multi-wire structures B. Mendoza, 17th Midwest Solid State Symposium, Indiana U., October 1989. 23.6 Longitudinal plasmon modes in a two-dimensional array of quasi-one-dimensional wires B.S. Mendoza and W.L. Schaich, APS March Meeting, Los Angeles. Bull. Am. Phys. Soc. 35, 768 (1990). 23.7 Second harmonic generation at a metal surface B.S. Mendoza and W.L. Schaich, 38/74 23.8 23.9 23.10 23.11 23.12 23.13 23.14 23.15 23.16 APS March Meeting, Cincinnati. Bull. Am. Phys. Soc. 36, 864 (1991). Second harmonic generation from a quantum dot array B.S. Mendoza and A. Guerrero, APS March Meeting, Indianapolis. Bull. Am. Phys. Soc. 37, 135 (1992). A Theoretical model for second harmonic generation in Si and Ge B.S. Mendoza, Workshop on optical properties of solids, Campinas, Brasil, November 1992. A Theoretical model for second harmonic generation in Si and Ge: Surface Anisotropies B.S. Mendoza, Seventh Latin-American Symposium on Surface Physics, Bariloche, Argentina, November 1992. Second Harmonic Generation at Crystal Surfaces W. Mochán and B.S. Mendoza, Seventh Latin-American Symposium on Surface Physics, Bariloche, Argentina, November 1992. A simple model for second harmonic generation B.S. Mendoza, 12th Latin-American Symposium on Solid State Physics, Pichidangui, Chile, November 1992. Generalized hydrodynamic model of inhomogeneous conductor in three, two and one dimensions M. del Castillo, W. Mochán and B.S. Mendoza, 12th Latin-American Symposium on Solid State Physics, Pichidangui, Chile, November 1992. Second harmonic Generation at Ag surfaces W. Mochán and B.S. Mendoza, APS March Meeting, Seattle. Bull. Am. Phys. Soc. 38, 586 (1993). Second harmonic Generation in Si and Ge B.S. Mendoza and W. Mochán, APS March Meeting, Seattle. Bull. Am. Phys. Soc. 38, 586 (1993). Second harmonic generation at Ag surfaces W. Mochán and B.S. Mendoza, International Congress on Electronic Transport an Optical Properties of Inhomogeneus Media-ETOPIM3, Guanajuato, August 1993. 39/74 23.17 Second harmonic generation of disordered dipolar arrays E. Jonguitud and B.S. Mendoza, International Congress on Electronic Transport an Optical Properties of Inhomogeneus Media-ETOPIM3, Guanajuato, August 1993. 23.18 Exactly solvable model of surface second harmonic generation W.L. Mochán and B.S. Mendoza, APS-March Meeting, Pittsburg. Bull. Am. Phys. Soc. 39, 68 (1994). 23.19 Second harmonic generation from disordered linear chains of polarizable spheres B.S. Mendoza and E. Jonguitud, APS-March Meeting, Pittsburg. Bull. Am. Phys. Soc. 39, 68 (1994). 23.20 Hydrodynamic model of second harmonic generation J. Maytorena, W.L. Mochán and B.S. Mendoza, APS-March Meeting, Pittsburg. Bull. Am. Phys. Soc. 39, 68 (1994). 23.21 Giant Local Field enhancement in second harmonic generation in a two-dimensional array of qunatum dots Bernardo S. Mendoza, Frontiers in Information Optics (ICO) Kyoto, April 1994. 23.22 Second harmonic generation at conductor surfaces with continuous profiles W.L. Mochán, J. Maytorena and B.S. Mendoza, IEEE/LEOS Nonlinear Optics, Hawaii (1994). 23.23 Exactly solvable model of surface second harmonic generation B.S. Mendoza and W.L. Mochán, IEEE/LEOS Nonlinear Optics, Hawaii (1994). 23.24 Hydrodynamic model of second harmonic generation at metal surfaces J. Maytorena, W.L. Mochán and B.S. Mendoza, CAM, Can-Cun, 1994. 23.25 Ionic and electronic contribution to the linear electro-optic coefficients of GaAs J. Curz, S. Acosta y B. Mendoza, CAM, Can-Cun, 1994. 23.26 Local Field Effect on the Linear and Second Order Susceptibility of Si and Ge B.S. Mendoza and W.L. Mochán, APS-March Meeting, San Jose. Bull. Am. Phys. Soc. 40, 511 (1995). 23.27 Non-Linear Response of a Disordered Linear Chain of Polarizable Spheres B.S. Mendoza and E. Jonguitud, 40/74 APS-March Meeting, San Jose. Bull. Am. Phys. Soc. 40, 511 (1995). 23.28 Plasmons in a Single spatially modulated quiasi-one dimensional quantum wire M. del Castillo, W.L. Mochán and B.S. Mendoza, APS-March Meeting, San Jose. Bull. Am. Phys. Soc. 40, 131 (1995). 23.29 Hydrodynamic model of second-harmonic generation at metal surfaces J.A. Maytorena, W.L. Mochán and B.S. Mendoza, Second Iberoamerican Meeting on Optics, Gunajuato, September 1995. 23.30 Second harmonic generation from disordered 1D chains of polarizable spheres J. Cruz, E. Jonguitud and Bernardo S. Mendoza, ETOPIM4, St. Petesburg-Moscow, July 1996. 23.31 Second harmonic generation at anisotropic and magnetized surfaces Vera L. Brundy, W. Luis Mochán, Bernardo S. Mendoza, A.V. Pethukov and T. Raising, Surface and Interface Optics 1997, Ålesund, Norway, June 1997. 23.32 Exactly solvable model of sum frequency generation Bernardo S. Mendoza, J. Cruz, W. Luis Mochán and J. Maytorena, Surface and Interface Optics 1997, Ålesund, Norway, June 1997. 23.33 Hydrodynamic model of sum and difference frequency generation at a metal surface J. Maytorena, W. Luis Mochán and Bernardo S. Mendoza, Surface and Interface Optics 1997, Ålesund, Norway, June 1997. 23.34 Optical reflectance anisotropy of Si(110):H Bernardo S. Mendoza, Rodolfo del Sole, and A. Shkrebti, Surface and Interface Optics 1997, Ålesund, Norway, June 1997. 23.35 What does the magnetization-induced second harmonic generation probe? V. L. Brudny, W. L. Mochán, B. S. Mendoza, A. V. Petukhov and Th. Rasing, EPIOPTICS 5, Erice, Italy, June 1998. 23.36 Visible-infrared sum and difference frequency generation at CN− covered Au W. L. Mochán, J. Maytorena and B. S. Mendoza, EPIOPTICS 5, Erice, Italy, June 1998. 23.37 Energy conservation in the three wave mixing at the bulk and the surface of centrosymmetric media W. L. Mochán, A. V. Petukhov, V. L. Brudny, Th. Rasing, J. Maytorena and B. S. Mendoza, EPIOPTICS 5, Erice, Italy, June 1998. 23.38 Microscopic theory of SHG at the Si(100) surface B. Mendoza, 41/74 International Materials Research Congress, Can-Cun, México, September 1998. Invited Talk. 23.39 Microscopic theory of SHG at the Si(100) surface B. Mendoza, A. Gaggiotti and R. Del Sole, Nonlinear Optics at Interfaces, Berlin, September 1998. 23.40 Energy conservation in surface nonlinear-optical spectroscopy A. V. Petukhov, V. Brudny, L. Mochán, J. Maytorena, B. Mendoza and Th. Rasing, Nonlinear Optics at Interfaces, Berlin, September 1998. 23.41 Energy Conservation in Surface Sum Frequency Generation Luis Mochán, Andrei V. Petukhov, Vera L. Brudny, Jesús Maytorena Córdova, and Bernardo S. Mendoza, US-Latin American-Canada-Caribbean Workshop on Molecular and Material Sciences: Theoretical and Computational Aspects, CCF, UNAM, Cuernavaca, México, February 1999. 23.42 Microscopic Theory of SHG at Si(100) B.S. Mendoza, APS March Meeting, Atlanta, 1999. 23.43 Theoretical approaches to surface Second Harmonic Generation J. Mejı́a, B. S. Mendoza, M. Palummo, G. Onnida, and R. Del Sole APS March Meeting, Minneapolis, Bull. Am. Phys. Soc. 45, 503 (2000). 23.44 Second harmonic generation from small spherical particles W. L. Mochán, B. S. Mendoza and V. Brudny, APS March Meeting, Minneapolis. Bull. Am. Phys. Soc. 45, 770 (2000). 23.45 Polarizable bond model for the optical response of reconstructed Si(100) surfaces N. Arzate and B. S. Mendoza APS March Meeting, Minneapolis. Bull. Am. Phys. Soc. 45, 967 (2000). 23.46 Polarizable bond model for reflectance anisotropy and second harmonic generation for Si(100) surfaces N. Arzate and Bernardo S. Mendoza, EPIOPTICS 2000, Erice, Italia. 23.47 Second Harmonic spectrsocopy of Si surfaces with H, Ge and B adsorbates: experiment and theory M.C. Downer, J.G. Ekerdt, D. Lim, P. Parkinson, V.I. Gavrilenko, R.Q.Wu, N. Arzate and B. S. Mendoza, Nonlinear Optics: Materials, Fundamentals and Applications, Kauai-Lihue, Hawaii, August 2000. 42/74 23.48 23.49 23.50 23.51 23.52 23.53 23.54 23.55 23.56 23.57 Sponsored by Optical Society of America. Platica Invitada. Second harmonic generation from small spherical particles W. L. Mochán, B. S. Mendoza and V. Brudny, Adriatico Research Conference on Lasers in Surface Science, Trieste, Italy, September 2000. Microscopic susceptibility effects in surface second harmonic generation Norberto Arzate and B. S. Mendoza, Adriatico Research Conference on Lasers in Surface Science, Trieste, Italy, September 2000. Second harmonic generation from small particle agregates W. L. Mochán, G. Ortiz, B. S. Mendoza and V. Brudny, APS March Meeting, Seattle, Bull. Am. Phys. Soc. 46, 698 (2001). Second harmonic generation from single domain Si(100) surfaces J. Mejı́a and B. S. Mendoza, APS March Meeting, Seattle, Bull. Am. Phys. Soc. 46, 1051 (2001). Second harmonic generation from single domain Si(100) surfaces J. Mejı́a and B. S. Mendoza, Optical Spectroscopy of Interfaces, Bad Honnef, Alemania, Mayo 20-23, 2001. Theoretical approaches to surface second harmonic generation vs experiment: Si(111): H 1 × 1 as a test case Jorge Mejı́a, Bernardo Mendoza, M. Palummo, G. Onida, R. Del Sole, S. Bergfeld and W. Daum, Optical Spectroscopy of Interfaces, Bad Honnef, Alemania, Mayo 20-23, 2001. Sum-frequency generation in the scattering of light by randomly rough metallic surfaces B. Mendoza, M. Leyva-Lucero, and E. Méndez, VII International Conference on Advanced Materials-ICAM2001, Cancun, México, Agosto 26-30, 2001. Platica Invitada. Second harmonic generation from single domain Si(100) surfaces J.E. Mejı́a, B.S. Mendoza, IV RIAO, Tandil, Argentina, Septiembre 3-7, 2001. Generación de segundo armónico en agregados de partı́culas pequeñas W.L. Mochán, G. Ortiza, V.L. Brudny, B.S. Mendoza, IV RIAO, Tandil, Argentina, Septiembre 3-7, 2001. Second harmonic generation by an infinite cylinder C.I. Valencia, E.R. Méndez, B. Mendoza, IV RIAO, Tandil, Argentina, Septiembre 3-7, 2001. 43/74 23.58 Multiple scattering effects in the sum-frequency generation from randomly rough metallic surfaces M.A. Leyva-Lucero, E.R. Méndez, B. Mendoza, IV RIAO, Tandil, Argentina, Septiembre 3-7, 2001. 23.59 Theoretical approaches to surface second harmonic generation vs experiment: Si(111): H 1 × 1 as a tests case J. Mejı́a, B.S. Mendoza, M. Palummo, G. Onida, R. Del Sole, S. Bergfeld and W. Daum, Nonlinear Optics at Interfaces, NOPTI’2001, Nijmegen, Holanda, Octubre 16-19, 2001. 23.60 Atomic plane analysis of surface second harmonic generation at a simple surface J. Mejı́a, C. Salazar, B. Mendoza, March Meeting APS, Austin, TX (2003) p. 1344. 23.61 Second harmonic generation from arrays of spherical particles W. Luis Mochán, Jesús Maytorena, Bernardo S. Mendoza, Vera Brudny March Meeting APS, Austin, TX (2003) p. 1345. 23.62 Second harmonic generation from arrays of spherical particles Vera Brudny, W.L. Mochán, J.A. Maytorena, and B.S. Mendoza, Optics of Surfaces and Interfaces, OSI-V, León, México, May 26-30, 2003. 23.63 Depth-resolved optical nanoscopy Luis Mochán, J. Maytorna, C. López-Bastidas, and B.S. Mendoza Optics of Surfaces and Interfaces, OSI-V, León, México, May 26-30, 2003. 23.64 Shift and injection currents in Si(100)2 × 1 surfaces N. Arzate, B.S. Mendoza, F. Nastos and J.E. Sipe Optics of Surfaces and Interfaces, OSI-V, León, México, May 26-30, 2003. 23.65 Reflectance anisotropy for porphyrin Octaester Langmuir-Schaefer films C. Castillo and B. Mendoza, Optics of Surfaces and Interfaces, OSI-V, León, México, May 26-30, 2003. 23.66 Spin-orbit effects on reflected anisotropy spectroscopy R.A. Vázquez-Nava, C. Castillo and B. Mendoza, Optics of Surfaces and Interfaces, OSI-V, León, México, May 26-30, 2003. 23.67 Layer-by-layer analysis of spectroscopic optical surface probes B. Mendoza, American Chemical Society, New York, Septiembre 7-11, p. TECH-27 (2003). Platica Invitada. 23.68 Second Harmonic Generation from nanoparticle W.L. Mochán, J.A. Maytorena, B.S. Mendoza, and V.L. Brudny, 44/74 XI Congreso Latinoamericano de Ciencias de Superficie y Aplicaciones, XI CLACSA, Pucón, Chile, diciembre 7-12, (2003). Platica Invitada. 23.69 Layer-by-layer analysis of spectroscopic optical surface probes B. Mendoza, Nonlinear and Stochastic Optics, Binational Consortium of Optics, Winter School, Tucson, January 10-13 (2004). Platica Invitada. 23.70 An optical study of the adsorption of H on the Si(100)2 × 1 surface N. Arzate and B. Mendoza, March Meeting APS, Montreal, Cánada (2004), p. 157. 23.71 Spin-orbit effects on reflectance anisotropy spectroscopy C. Castillo, R. Vázquez-Nava and B. Mendoza, March Meeting APS, Montreal, Cánada (2004), p. 456. 23.72 Reflectance anisotropy for porphyrin ostaester films R. Vázquez-Nava , C. Castillo, and B. Mendoza, March Meeting APS, Montreal, Cánada (2004), p. 1131. 23.73 Second harmonic generation from Si(111) (7 × 7) surfaces J. E. Mejı́a and Bernardo S. Mendoza, Workshop Nanoscience for Advanced Applications: on crossroads of disciplines, Guanajuato, México, Febrero 16-19 (2005). 23.74 Spin-orbit effects on reflectance anisotropy spectroscopy of a clean CdTe(001) surface R. A. Vázquez-Nava, B. S. Mendoza and N. Arzate, Workshop Nanoscience for advanced applications: on crossroads of disciplines, Guanajuato, Febrero 16-19 (2005). 23.75 Band structure calculations of the linear optical response of the clean and hydrogenated Si(100) surface, B. Mendoza, N. Arzate, F. Nastos, and J. Sipe, March Meeting APS, Los Angeles, p. 949, 2005. 23.76 SHG from bulk and surface of nanoparticle composites, L. Mochán and B. Mendoza, March Meeting APS, Los Angeles, p. 1164 (2005). 23.77 Spin-orbit effects on reflectance anisotropy spectroscopy of a clean CdTe (001) surface R. Vázquez, N. Arzate, and B. Mendoza, March Meeting APS, Los Angeles, p. 576 (2005). 23.78 Theoretical study of the optical anisotropy response of molecular leyered systems R. A. Vázquez-Nava, B. S. Mendoza and N. Arzate, Optics of Surfaces and Interfaces, OSI-VI, Dinamarca, junio 2005. 45/74 23.79 Spin-Orbit effects on the optical anisotropy of semiconductor surfaces R. A. Vázquez-Nava, B. S. Mendoza and N. Arzate, Optics of Surfaces and Interfaces, OSI-VI, Dinamarca, junio 2005. 23.80 Assembling and partial disordering during the absorption of Sb on the GaAs(110) surface B. S. Mendoza, N. Arzate and R. A. Vázquez-Nava, Optics of Surfaces and Interfaces, OSI-VI, Dinamarca, junio 2005. 23.81 Layer-by-Layer microscopic calculation for the non-linear response of the Si(111) surfaces J. E. Mejı́a, G. J. Serratos and B. S. Mendoza, Optics of Surfaces and Interfaces, OSI-VI, Dinamarca, junio 2005. 23.82 Band structure calculations of the surface linear optical response of the clean and hydrogenated Si(100) surface B. S. Mendoza, N. Arzate, F. Nastos and J. Sipe, Optics of Surfaces and Interfaces, OSI-VI, Dinamarca, junio 2005. 23.83 Optical spin injection study on the Si(111) surface N. Arzate, B. S. Mendoza, J. L. Cabellos, F. Nastos and J. Sipe, Optics of Surfaces and Interfaces, OSI-VI, Dinamarca, junio 2005. 23.84 Single-Beam and Enhanced Two-Beam Second-Harmonic-Generation from Silicon Nano-interfaces L. Sun, P. Figliozzi, Y. Jiang, M.C. Downer, W L. Mochan, B.S. Mendoza, 33rd Conference o the Physics and Chemistry of Semiconductoir Interfaces, Florida, January 2006. 23.85 Coherent superposition of quadrupolar SHG from isotropic materials using two orthogonally polarized laser beams L. Sun, P. Figliozzi, Y. Q. An, M. C. Downer, W. L. Mochán and B. S. Mendoza, CLEO/QELS 2006 Long Beach, California. 23.86 Reflectance anisotropy spectra of CdTe 001 surfaces, R. Vázquez, B. Mendoza and N. Narzate, Bull. Am. Phys. Soc. 51, 604 (2006). 23.87 Single- and enhanced two-beam second-harmonic generation from silicon nanocrystals by use of spatially inhomogeneous femtosecond pulses, Bernardo Mendoza, 2nd Workshop: Nanoscience for advanced application on the crossroad of disciplines, IFUG, León, september 2006. 23.88 Layer-by-layer microscopic calculation for the non-linear response of the Si(111) 7×7 surface, J. Mejı́a and B. Mendoza, 1st Meeting of the European Optical Society, Paris, October, 2006. 46/74 23.89 Reflectance anisotropy spectra of CdTe(001) surfaces, R. Vazquez, N. Arzate and B. Mendoza, 1st Meeting of the European Optical Society, Paris, October, 2006. 23.90 Electronic and optical study of BN nanotubes, N. Arzate, C.M. Gonzalez, F. Nastos, B. S. Mendoza, and J. E. Sipe, 1st Meeting of the European Optical Society, Paris, October, 2006. 23.91 Bi-anisotropic optical properties of two-dimensional arrays of metallo-dielectric cylinders, B. Martı́nez, G. Ortiz, B.S. Mendoza, and W.L. Mochán, 1st Meeting of the European Optical Society, Paris, October, 2006. 23.92 Single-beam and enhanced two-beam second-harmonic generation from silicon nanocrystals by use of spatially inhomogeneous femtosecond pulses, B.S. Mendoza, W.L. Mochán, P. Figliozzi, L. Sun, Y. Jiang, N. Matlis, B. Mattern, M.C. Downer, S.P. Withrow, and C.W. White, 1st Meeting of the European Optical Society, Paris, October, 2006. 23.93 Optical properties of metamaterials, B.S. Mendoza, B. Martı́nez, and G. Ortiz, Binational Consortium of Optics, 3rd school, Optics of novel materials and of condensed matter, Tucson, November, 2006. 23.94 Layer-by-layer microscopic calculation for the non-linear response of the Si(111)7 × 7 surfaces, J. Mejı́a and B. Mendoza, XVIII Latin American Symposium on Solid State Physics, Puebla, November 2006. 23.95 Linear Optical Response of BN nanotubes, N. Arzate, C.M. González, F. Nastos, B. S. Mendoza, and J.E. Sipe, XVIII Latin American Symposium on Solid State Physics (SLAFES06), Puebla, México, 20-24 Nov. 2006. 23.96 Optical Spin Injection On Semiconductor Surfaces B. Mendoza, J.L. Cabellos, T. Rangel, N. Arazte, F. Nastos, and J. Sipe Optics of Surfaces and Interfaces VII, Jackson Hole, USA, 2007 23.97 Optical Injection Current on Semiconductor Surfaces J.L. Cabellos, B. Mendoza, F. Nastos, J. Sipe and A. Shkrebtii Optics of Surfaces and Interfaces VII, Jackson Hole, USA, 2007 23.98 Relfectance anisotropy spectroscopy of partly Sb-covered GaAs(110) surfaces B. Mendoza, N. Arzate and R. Vázquez Optics of Surfaces and Interfaces VII, Jackson Hole, USA, 2007 23.99 Optical propertie of 2D arrays of metallo-dielectric metamaterials B. Martı́nez, G. Ortiz, B. Mendoza and W.L. Mochán Optics of Surfaces and Interfaces VII, Jackson Hole, USA, 2007 47/74 23.100 Effective dielectric response of metallo-dielectric metamaterials B. Martı́nez, G. Ortiz, B. Mendoza and W.L. Mochán Giambiaggi School on Metamaterials, Buenos Aires, Argentina, julio 2007. 23.101 Optical spin injection on semiconductor surfaces B.S. Mendoza, J.L. Cabellos, T. Rangel, N. Arzate, F. Nastos y J. Sipe 6th Ibero-american conference on optics (RIAO), Sao Paulo, Brasil, octubre (2007). 23.102 Effective dielectric response of metamaterials G. Ortiz, B. Martı́nez y B.S. Mendoza 6th Ibero-american conference on optics (RIAO), Sao Paulo, Brasil, octubre (2007). 23.103 Shift- and injection-current optical response of BN nanotubes, N. Arzate, F. Nastos, R.A. Vázquez-Nava, C.M. González, B.S. Mendoza, and J.E. Sipe, APS March Meeting, New Orleans, Louisiana, USA., 10-14 Marzo del 2008. 23.104 Reflectance anisotropy spectroscopy of II-VI semiconductor surfaces, R.A. VázquezNava, N. Arzate and B.S. Mendoza, APS March Meeting, New Orleans, Louisiana, USA., 10-14 Marzo del 2008. 23.105 Theoretical study of the optical response of the adsorption of Sb on the GaAs(110) surface, R.A. Vázquez-Nava, N. Arzate and B.S. Mendoza, International School on vibrational Spectroscopies: a hands-on introduction to abinit, Queretaro, junio del 2008. 23.106 Optical Spin Injection on Semiconductor Surfaces, B. Mendoza, IEEE/LEOS Summer Topical Meeting: Special Symposium on Photonics in Mexico, Acapulco, 21 de julio, 2008. Platica Invitada. 23.107 Optical Properties of Nanostructured Metamaterials, B. Martinez,G. Ortiz, B. Mendoza, W.L. Mochán, IEEE/LEOS Summer Topical Meeting: Special Symposium on Photonics in México, Acapulco, 21 de julio, 2008. 23.108 Optical Properties of Nanostructured Metamaterials, B. Martinez,G. Ortiz, H. Sanchez, B. Mendoza, W.L. Mochán, XVII International Materials Research Congress, Cancún, Yuc. México, 17-21 Agosto 2008. 23.109 Shift- and injection-current optical response of boron nitride nanotubes, N. Arzate, F. Nastos, R.A. Vázquez-Nava, C.M. González, B.S. Mendoza, and J.E. Sipe, XVII International Materials Research Congress, Cancún, Yuc. México, 17-21 Agosto 2008. 23.110 Second Harmonic Generation of Nano-Spheres, B. Mendoza, W.L. Mochán and M. Downer, 48/74 Fifth International topical meeting on nanostructured materials and nanotechnology, Nanotech 2008, México, D.F., 24-26 Noviembre 2008. 23.111 Optical shift- and injection-current response of nitride nanotubes, N. Arzate, F. Nastos, R.A. Vázquez-Nava, C.M. González, B.S. Mendoza, and J.E. Sipe, Fifth International topical meeting on nanostructured materials and nanotechnology, Nanotech 2008, México, D.F., 24-26 Noviembre 2008. 24 Moderador en Congresos 24.1 Optica no-lineal, XLIII Congreso Nacional de Fı́sica, Puebla, Puebla, Méx. Nov. 2000. 24.2 Quantum Optics, Quantum Control, and Ultrafast Processes APS March Meeting, Los Angeles, California, March 21-25 (2005). 24.3 Mesa Redonda: Estado Sólido V: Propiedades opticas de posos, hilos y puntos cuánticos. B. Mendoza, G. Hernández y I. Hernández, L Congreso Nacional De Fı́sica. Boca del Rio, octubre 2007. 25 Citas Bibliográficas Actualizadas al 12 de enero del 2008. 555 Citas Con un ∗ (asterisco) se dan las citas de coautores 25.1 Del Artı́culo 7.2.1: Láser de nitrógeno a presión atmosférica 25.1.1 Fernandez-Guasti M, Perez S, Iturbide D, Haro E, Escobar L, Habichayn P., Garcia A, Cudney R, Garcia C, Gonzalez E, Rev. Mex. Fis. 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ISBN 90-9011085-2 (1997), cap. 2. 25.159.1 ∗ Recamier, J, Mochan, WL, Maytorena, JA, Nonlinear response of a harmonic diatomic molecule: Algebraic nonperturbative calculation, PHYSICAL REVIEW A (2005), 72 p. 023805. 25.160.2 ∗ Recamier, J and Mochan, WL and Maytorena, J, Exact non linear response of a harmonic oscillator, PROCEEDINGS OF THE SOCIETY OF PHOTO-OPTICAL INSTRUMENTATION ENGINEERS (SPIE) (2004), 5622 p.513-517. 25.17 Del Artı́culo 7.2.19: Local Field Effect in the Second Harmonic Generation Spectra of Si Surfaces 25.161.1 Sanchez-Castillo, A, Roman-Velazquez, CE, Noguez, C, Optical circular dichroism of single-wall carbon nanotubes PHYSICAL REVIEW B (2006), 73 p. 045401. 25.162.2 Bechstedt, F, Del Sole, R, Glutsch, S, Hahn, PH, Pulci, O, Schmidt, WG, Many-body and overlayer effects on surface optical properties PHYSICA STATUS SOLIDI B-BASIC RESEARCH (2003), 240 p. 469. 25.163.3 Wijers, CMJ, The local field and what it means PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (2001), 188 p. 1251. 25.164.4 Galamic-Mulaomerovic, S, Hogan, CD, Patterson, CH, Eigenfunctions of the inverse dielectric functions and response functions of silicon and argon, PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (2001), 188 p. 1291. 25.165.5 Nicastro, M, Galamic-Mulamerovic, S, Patterson, CH, Multipolar contributions to electron self-energies: extreme tight binding model, JOURNAL OF PHYSICS-CONDENSED MATTER (2001), 13 p. 1215. 25.166.6 Rodriguez-Rosales, AA, Estudio de propiedades ópticas nolineales en nuevos materiales argánicos monoméricos, Tesis de Maestrı́a, (2001), UNAM. 25.167.7 Mitchell, S, Boukherroub, R, Anderson, S, Second Harmonic Generation at Chemically Modified Si(111) Surfaces, J. 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ISBN 90-9011085-2 (1997), cap. 2 and app. B. 25.178.1 ∗ Mochan, WL, SHG from bulk and surface of nanoparticle composites, PHYSICA STATUS SOLIDI C-CURRENT TOPICS IN SOLID STATE PHYSICS (2005), 2 p. 4062-4066. 25.179.2 ∗ Recamier, J, Mochan, WL, Maytorena, JA, Nonlinear response of a harmonic diatomic molecule: Algebraic nonperturbative calculation, PHYSICAL REVIEW A (2005), 72 p. 023805. 25.18 Del Artı́culo 7.2.20: Polarizable bond model for second harmonic generation 25.180.1 Adles, E. J. and Aspnes, D. E., Application of the anisotropic bond model to second-harmonic generation from amorphous media, PHYSICAL REVIEW B (2008), 77 p. 165102. 25.181.2 An, Y. Q. and Carriles, R. and Downer, M. C., Absolute phase and amplitude of second-order nonlinear optical susceptibility components at Si(001) interfaces, PHYSICAL REVIEW B (2007), 75 p. 241307. 25.182.3 McGilp, J. 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JOURNAL OF PHYSICAL 25.204.25 Lupke, G, Characterization of semiconductor interfaces by second-harmonic generation, SURFACE SCIENCE REPORTS (1999), 35 p. 77. 25.205.26 Lohner, FP, Villaeys, AA, Anisotropy analysis of the SHG intensity by surfaces of simple metals OPTICS COMMUNICATIONS (1998), 154 p. 217. 25.206.27 Hogan, CD, Patterson, CH, Reflectance anisotropy of silicon surfaces: Discrete dipole calculation PHYSICAL REVIEW B (1998), 57 p. 14843. 25.207.28 Dadap, JI, Xu, Z, Hu, XF, Downer, MC, Russell, NM, Ekerdt, JG, Aktsipetrov, OA, Second-harmonic spectroscopy of a Si(001) surface during calibrated variations in temperature and hydrogen coverage, PHYSICAL REVIEW B (1997), 56 p. 13367. 25.208.29 van Hasselt, K, Tesis de Doctorado, U. de Nijmegen, Holanda. ISBN 90-9011085-2 (1997), cap. 2 and app. B. 25.209.1 ∗ Mochan, WL, SHG from bulk and surface of nanoparticle composites, PHYSICA STATUS SOLIDI C-CURRENT TOPICS IN SOLID STATE PHYSICS (2005), 2 p. 4062-4066. 25.210.2 ∗ Recamier, J, Mochan, WL, Maytorena, JA, Nonlinear response of a harmonic diatomic molecule: Algebraic nonperturbative calculation, PHYSICAL REVIEW A (2005), 72 p. 023805. 55/74 25.211.3 ∗ MadrigalMelchor, J, PerezRodriguez, F, Maytorena, JA, Mochan, WL, An optical spectroscopy for detecting quantized polarization waves of excitons, APPLIED PHYSICS LETTERS (1997), 71 p. 69. 25.19 Del Artı́culo 7.2.22: Theory of surface sum frequency generation spectroscopy 25.212.1 Coutaz, JL and Kadlec, F and Kuzel, P, Optical rectification at metal surfaces investigated in the terahertz frequency range, PROCEEDINGS OF THE SOCIETY OF PHOTO-OPTICAL INSTRUMENTATION ENGINEERS (SPIE) (2006), 6257 p. M2570. 25.213.2 Kadlec, F, Kuzel, P, Coutaz, JL, Optical rectification at metal surfaces OPTICS LETTERS (2004), 29 p. 2674. 25.214.3 Lambert, AG, Neivandt, DJ, Briggs, AM, Usadi, EW, Davies, PB, Interference effects in sum frequency spectra from monolayers on composite dielectric/metal substrates, JOURNAL OF PHYSICAL CHEMISTRY B (2002), 106 p. 5461. 25.215.4 Lupke, G, Characterization of semiconductor interfaces by second-harmonic generation, SURFACE SCIENCE REPORTS (1999), 35 p. 77. 25.216.5 McGilp, JF, Second-harmonic generation at semiconductor and metal surfaces SURFACE REVIEW AND LETTERS (1999), 6 p. 529. 25.217.6 Somorjai, GA, Rupprechter, G, Molecular studies of catalytic reactions on crystal surfaces at high pressures and high temperatures by infrared-visible sum frequency, generation (SFG) surface vibrational spectroscopy, JOURNAL OF PHYSICAL CHEMISTRY B (1999), 103 p. 1623. 25.218.7 Liebsch, A, Theory of sum frequency generation from metal surfaces APPLIED PHYSICS B-LASERS AND OPTICS (1999), 68 p. 301. 25.219.8 Lohner, FP, Villaeys, AA, Second harmonic generation polarization anisotropy of Al surfaces: the band model approach, SURFACE SCIENCE (1999), 422 p. 17. 25.220.9 Lohner, FP, Villaeys, AA, Anisotropy analysis of the SHG intensity by surfaces of simple metals OPTICS COMMUNICATIONS (1998), 154 p. 217. 25.221.1 ∗ 25.222.2 ∗ Recamier, J, Mochan, WL, Maytorena, JA, Nonlinear response of a harmonic diatomic molecule: Algebraic nonperturbative calculation, PHYSICAL REVIEW A (2005), 72 p. 023805. Vazquez-Nava, RA, Cocoletzi, GH, del Castillo-Mussot, M, Mochan, WL, Electron energy-loss spectroscopy on the surface of conducting superlattices in the presence of plasma waves, PHYSICAL REVIEW B (1998), 57 p. 14642. 25.20 Del Artı́culo 7.2.23: Hydrodynamic model for sum and difference frequency generation at metal surfaces 25.223.1 Kong Linghua and Yan Baorong and Hu Xiwei, Dispersion relations of longitudinal plasmons in one, two and three dimensional electron gas of metals, PLASMA SCIENCE & TECHNOLOGY (2007), 9 p. 519-525. 25.224.2 Coutaz, JL and Kadlec, F and Kuzel, P, Optical rectification at metal surfaces investigated in the terahertz frequency range, PROCEEDINGS OF THE SOCIETY OF PHOTO-OPTICAL INSTRUMENTATION ENGINEERS (SPIE) (2006), 6257 p. M2570. 25.225.3 Kadlec, F, Kuzel, P, Coutaz, JL, Optical rectification at metal surfaces OPTICS LETTERS (2004), 29 p. 2674. 25.226.4 Rodriguez-Rosales, AA, Estudio de propiedades ópticas nolineales en nuevos materiales argánicos monoméricos, Tesis de Maestrı́a, (2001), UNAM. 25.227.5 Link, G, von Baltz, R, Hydrodynamic description of surface plasmons: Nonexistence of the unrestricted half-space solution, PHYSICAL REVIEW B (1999), 60 p. 16157. 25.228.6 Liebsch, A, Theory of sum frequency generation from metal surfaces APPLIED PHYSICS B-LASERS AND OPTICS (1999), 68 p. 301. 25.229.7 Lohner, FP, Villaeys, AA, Second harmonic generation polarization anisotropy of Al surfaces: the band model approach, SURFACE SCIENCE (1999), 422 p. 17. 25.230.8 Lohner, FP, Villaeys, AA, Anisotropy analysis of the SHG intensity by surfaces of simple metals OPTICS COMMUNICATIONS (1998), 154 p. 217. 25.231.9 Liebsch, A, Electronic Excitations at Metal Surfaces, (1998), Chap. 5. Plenum, N.Y. 25.21 Del Artı́culo 7.2.24: Theory of optical reflectance anisotropy of the natural Si(110) surfaces 25.232.1 D. Papadimitriou and W. Richter, Highly sensitive strain detection in silicon by reflectance anisotropy spectroscopy, Physical Review B 72 075212 (2005). 25.233.2 Neng-Ping Wang, Michael Rohlfing, Peter Krüger, and Johannes Pollmann, Quasiparticle band structure and optical spectrum of LiF(001), Physical Review B 67 115111 (2003). 25.234.3 Bechstedt, F and Del Sole, R and Glutsch, S and Hahn, PH and Pulci, O and Schmidt, WG, Many-body and overlayer effects on surface optical properties, PHYSICA STATUS SOLIDI B (2003), 240 p. 469-479. 25.235.4 Schmidt, WG and Hahn, PH and Bechstedt, F, Excitonic and local-field effects in optical spectra from real-space time-domain calculations, HIGH PERFORMANCE COMPUTING IN SCIENCE AND ENGINEERING ‘02 (2003), ISBN 3-540-43860-2 p. 133-148. 25.236.5 W. G. Schmidt, S. Glutsch, P. H. Hahn, and F. Bechstedt, Efficient O(N2) method to solve the Bethe-Salpeter equation, Physical Review B 67 085307 (2003). 25.237.6 P. H. Hahn, W. G. Schmidt, and F. Bechstedt, Bulk Excitonic Effects in Surface Optical Spectra, Physical Review Letters 88 016402 (2002). 25.238.7 W. G. Schmidt, F. Bechstedt, W. Lu, and J. Bernholc, Interplay of surface reconstruction and surface electric fields in the optical anisotropy of GaAs(001), Physical Review B 66 085334 (2002). 25.239.8 Rohlfing, R, Quasiparticle spectrum and optical excitations of semiconductor surfaces, APPLIED PHYSICS A-MATERIALS SCIENCE & PROCESSING (2001), 72 p. 413-419. 25.240.9 Bernholc, J and Briggs, EL and Nardelli, MB, Large-scale, multilevel solutions of Kohn-Sham equations: methodology and applications, NATO SCIENCE SERIES, SUB-SERIES III: COMPUTER AND SYSTEMS SCIENCES (2001), 177 p. 65-89. 25.241.10 F. Bechstedt, W.G. Schmidt, P.H. Hahn, Towards a Complete Many-Body Description: Optical Response of Real Surfaces, physica status solidi (a) 188 1383 (2001). 25.242.11 Hingerl, K, Balderas-Navarro, RE, Bonnani, A, Tichopadek, P, Schmidt, WG, On the origin of resonance features in reflectance difference data of silicon, Applied Surface Science (2001), 175, p. 769. 25.243.12 Wang, Y, Li, SFY, Ye, JH, In situ electrochemical ATR-FTIR spectrsocopic investigation of hydrogen-treminated si(110) surface in dilute NH4F solution, Journal of the Electrochemical Society (2001), 148, p. E439. 56/74 25.244.13 W. G. Schmidt and J. Bernholc, Step-induced optical anisotropy of Si(111):H surfaces, Physical Review B 61 7604 (2000). 25.245.14 Schmidt, WG, Bechstedt, F, Bernholc, J, Understanding reflectance anisotropy: surface-state signatures and bulk-related features, J. Vacuum Sci. & Techno. B (2000), 18, p. 2215. 25.246.15 Michael Rohlfing and Steven G. Louie, Excitons and Optical Spectrum of the Si(111)-(2x1) Surface, Physical Review Letters 83 856 (1999). 25.247.16 W. G. Schmidt, E. L. Briggs, J. Bernholc, and F. Bechstedt, Structural fingerprints in the reflectance anisotropy spectra of InP(001)(2x4) surfaces, Physical Review B 59 2234 (1999). 25.248.17 Rohlfing, M, Louie, S, Optical reflectivity of the Si(111)-(2x1) surface-the role of the electron hole interaction, Phys. Stat. Sol. A (1999), 175, p. 17 25.249.18 Rohlfing, M, Louie, S, Excitons and the optical spectrum of the Si(111)-(2x1) surface, Phys. Rev. Lett. (1999), 83, p. 856. 25.250.1 ∗ Rodolfo Del Sole and Giovanni Onida, Surface versus crystal-termination effects in the optical properties of surfaces, Physical Review B 60 5523 (1999). 25.251.2 ∗ Chiaradia, P, Del Sole, R, Differential-reflectance spectrsocopy and reflectance-anisotropy spectroscopy on semiconductor surfaces, Sur. Review and Lett. (1999), 6, p. 517. 25.22 Del Artı́culo 7.2.25: Energy conservation and the Manley Rowe relations in surface non linear optical spectroscopy 25.252.1 Hagmann, Mark J., Possibility of generating terahertz radiation by photomixing with clusters of carbon nanotubes, JOURNAL OF VACUUM SCIENCE & TECHNOLOGY B (2008), 26 p. 794-799. 25.253.2 Hagmann, Mark J., Simulations of high-power pulsed terahertz sources using laser-assisted field emission, 2007 IEEE 20TH INTERNATIONAL VACUUM NANOELECTRONICS CONFERENCE (2007), ISBN 978-1-4244-1133-7, p. 149-150. 25.254.3 Roke, S, Kleyn, AW, Bonn, M, Femtosecond sum frequency generation at the metal-liquid interface SURFACE SCIENCE (2005), 593 p. 79. 25.255.4 Neacsu, CC, Reider, GA, Raschke, MB, Second-harmonic generation from nanoscopic metal tips: Symmetry selection rules for single asymmetric nanostructures, PHYSICAL REVIEW B (2005), 71 p. 201402. 25.256.5 Raschke, MB, Shen, YR, Nonlinear optical spectroscopy of solid interfaces CURRENT OPINION IN SOLID STATE & MATERIALS SCIENCE (2004), 8 p. 343. 25.257.6 Vidal, F, Tadjeddine, A, Sum-firequency generation spectroscopy of interfaces REPORTS ON PROGRESS IN PHYSICS (2005), 68 p. 1095. 25.258.1 ∗ 25.259.2 ∗ Roke, S, Bonn, M, Petukhov, AV, Nonlinear optical scattering: The concept of effective susceptibility PHYSICAL REVIEW B (2004), 70 p. 115106. 25.260.3 ∗ Kirilyuk, A, Rasing, T, Magnetization-induced-second-harmonic generation from surfaces and interfaces, JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B-OPTICAL PHYSICS (2005), 22 p. 148. Sato, K, Kodama, A, Miyamoto, M, Petukhov, AV, Takanashi, K, Mitani, S, Fujimori, H, Kirilyuk, A, Rasing, T, Anisotropic magnetization-induced second harmonic generation in Fe/Au superlattices, PHYSICAL REVIEW B (2001), 6418 p. 184427. 25.23 Del Artı́culo 7.2.26: Magnetic dipolium model of magnetization induced surface second harmonic generation 25.261.1 Hamrle, J, Polerecky, L, Ferre, J, Theory of second-harmonic generation from multilayer systems based on electric point-dipole radiation: Application to magnetic multilayers, PHYSICAL REVIEW B (2003), 68 p. 144401. 25.24 Del Artı́culo 7.2.28: Microscopic theory of second harmonic generation at the Si(100) surface 25.262.1 Gavrilenko, V. I., Differential reflectance and second-harmonic generation of the Si/SiO2 interface from first principles, PHYSICAL REVIEW B (2008), 77 p. 155311. 25.263.2 Duerr, M. and Hoefer, U., Dissociative adsorption of molecular hydrogen on silicon surfaces, SURFACE SCIENCE REPORTS (2006), 61 p. 465-526. 25.264.3 Omote, M, Kitaoka, H, Kobayashi, E, Suzuki, O, Aratake, K, Sano, H, Mizutani, G, Wolf, W, Podloucky, R, Spectral, tensor, and ab initio theoretical analysis of optical second harmonic generation from the rutile TiO2(110) and (001) faces, JOURNAL OF PHYSICS-CONDENSED MATTER (2005), 17 p. S175. 25.265.4 Yilmaz, MB, Rajagopal, A, Zimmermann, FM, Quenching of optical second harmonic generation at the Si(001) surface by hydrogen adsorption, PHYSICAL REVIEW B (2004), 69 p. 125413. 25.266.5 Calmels, L, Inglesfield, JE, Crampin, S, Arola, E, Rasing, T, Complex frequency technique for linear and second harmonic optical properties of metallic surfaces, COMPUTER PHYSICS COMMUNICATIONS (2003), 151 p. 251. 25.267.6 Sano, H, Mizutani, G, Wolf, W, Podloucky, R, Ab initio study of linear and nonlinear optical responses of Si(111) surfaces, PHYSICAL REVIEW B (2002), 66 p. 195338. 25.268.7 Gruhn, W, Kityk, IV, Benet, S, Photoinduced optical second harmonic generation in Fe-Co metallic spin glasses, MATERIALS LETTERS (2002), 55 p. 158. 25.269.8 Dolgova, TV, Schuhmacher, D, Marowsky, G, Fedyanin, AA, Aktsipetrov, OA, Second-harmonic interferometric spectroscopy of buried interfaces of column IV semiconductors, APPLIED PHYSICS B-LASERS AND OPTICS (2002), 74 p. 653. 25.270.9 Mishina, ED, Morosov, AI, Yu, QK, Nakabayashi, S, Rasing, T, Nonlinear optics for surface phase transitions APPLIED PHYSICS B-LASERS AND OPTICS (2002), 74 p. 765. 25.271.10 Gavrilenko, VI, Wu, RQ, Second harmonic generation of GaN(0001) PHYSICAL REVIEW B (2002), 65 p. 035405. 25.272.11 Wijers, CMJ, The local field and what it means PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (2001), 188 p. 1251. 25.273.12 Gavrilenko, VI, Ab initio theory of second harmonic generation from semiconductor surfaces and interfaces, PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (2001), 188 p. 1267. 25.274.13 Falasconi, M, Andreani, LC, Malvezzi, AM, Patrini, M, Mulloni, V, Pavesi, L, Bulk and surface contributions to second-order susceptibility in crystalline and porous silicon by second-harmonic generation, SURFACE SCIENCE (2001), 481 p. 105. 57/74 25.275.14 Gavrilenko, VI, Wu, RQ, Downer, MC, Ekerdt, JG, Lim, D, Parkinson, P, Optical second-harmonic spectra of Si(001) with H and Ge adatoms: First-principles theory and experiment, PHYSICAL REVIEW B (2001), 63 p. 165325. 25.276.15 Rodriguez-Rosales, AA, Estudio de propiedades ópticas nolineales en nuevos materiales argánicos monoméricos, Tesis de Maestrı́a, (2001), UNAM. 25.277.16 Jeong, JW, Shin, SC, Lyubchanskii, IL, Varyukhin, VN, Strain-induced three-photon effects PHYSICAL REVIEW B (2000), 62 p. 13455. 25.278.17 Gavrilenko, VI, Wu, RQ, Downer, MC, Ekerdt, JG, Lim, D, Parkinson, P, Optical second harmonic spectra of silicon-adatom surfaces: theory and experiment, THIN SOLID FILMS (2000), 364 p. 1. 25.279.18 Lupke, G, Characterization of semiconductor interfaces by second-harmonic generation, SURFACE SCIENCE REPORTS (1999), 35 p. 77. 25.280.19 Aktsipetrov, OA, Fedyanin, AA, Melnikov, AV, Mishina, ED, Rubtsov, AN, Anderson, MH, Wilson, PT, ter Beek, H, Hu, XF, Dadap, JI, Downer, MC, dc-electric-field-induced and low-frequency electromodulation second-harmonic generation spectroscopy of Si(001)-SiO2 interfaces, PHYSICAL REVIEW B (1999), 60 p. 8924. 25.281.20 Wilson, PT, Jiang, Y, Aktsipetrov, OA, Mishina, ED, Downer, MC, Frequency-domain interferometric second-harmonic spectroscopy OPTICS LETTERS (1999), 24 p. 496. 25.282.21 Parkinson, PS, Lim, D, Bungener, R, Ekerdt, JG, Downer, MC, Second-harmonic spectroscopy of Ge/Si(001) and Si1-xGex(001)/Si(001) APPLIED PHYSICS B-LASERS AND OPTICS (1999), 68 p. 641. 25.283.22 Raschke, MB, Hofer, U, Equilibrium and nonequilibrium hydrogen coverages on vicinal Si(001) surfaces: Diffusion barriers and binding energies, PHYSICAL REVIEW B (1999), 59 p. 2783. 25.284.1 ∗ Del Sole, R, Present status of the theory of surface optical properties PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (1998), 170 p. 183. 25.25 Del Artı́culo 7.2.30: Microscopic theory of second harmonic generation at the Si(100)2× 1 surface 25.285.1 ∗ Onida, G, Del Sole, R, Palummo, M, Pulci, O, Reining, L, Ab-initio calculation of the optical properties of surfaces PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (1998), 170 p. 365. 25.26 Del Artı́culo 7.2.31: Visible infrared difference frequency generation at CN− covered Au 25.286.1 Buck, M, Himmelhaus, M, Vibrational spectroscopy of interfaces by infrared-visible sum frequency generation, JOURNAL OF VACUUM SCIENCE & TECHNOLOGY A-VACUUM SURFACES AND FILMS (2001), 19 p. 2717. 25.27 Del Artı́culo 7.2.33: DC electric field modified second harmonic generation at the Si(100) surface 25.287.1 Rodriguez-Rosales, AA, Estudio de propiedades ópticas nolineales en nuevos materiales argánicos monoméricos, Tesis de Maestrı́a, (2001), UNAM. 25.28 Del Artı́culo 7.2.34: Ab initio optical properties of Si(100) 25.288.1 Witkowski, N. and Coustel, R. and Pluchery, O. and Borensztein, Y., RAS: An efficient probe to characterize Si(001)-(2 X 1) surfaces, SURFACE SCIENCE (2006), 24 p. 1142-1149. 25.289.2 Witkowski, N and Pluchery, O and Royer, S and Borensztein, Y, RAS investigation of benzene adsorption on vicinal single-domain Si(001)-(2 x 1) surfaces, PHYSICA STATUS SOLIDI C (2005), 2 p. 4053-4057. 25.290.3 Pluchery, O, Witkowski, N, Borensztein, Y, Investigation of molecule chemisorption on Si(001)2 x 1 surfaces by surface reflectance spectroscopies, PHYSICA STATUS SOLIDI B-BASIC SOLID STATE PHYSICS (2005), 242 p. 2696. 25.291.4 Borensztein, Y, Pluchery, O, Witkowski, N, Probing the Si-Si dimer breaking of Si(100)2x1 surfaces upon molecule adsorption by optical spectroscopy, PHYSICAL REVIEW LETTERS (2005), 95 p. 117402. 25.292.5 Witkowski, N, Pluchery, O, Borensztein, Y, Optical investigation of benzene adsorption on vicinal single-domain Si(001)-(2x1) surfaces, PHYSICAL REVIEW B (2005), 72 p. 075354. 25.293.6 Weightman, P, Martin, DS, Cole, RJ, Farrell, T, Reflection anisotropy spectroscopy REPORTS ON PROGRESS IN PHYSICS (2005), 68 p. 1251. 25.294.7 Borensztein, Y, Witkowski, N, Optical response of clean and hydrogen-covered vicinal Si(001) 2x1 surfaces, JOURNAL OF PHYSICS-CONDENSED MATTER (2004), 16 p. S4301. 25.295.8 Cramariuc, O, Hukka, TI, Rantala, TT, A DFT study of asymmetric meso-substituted porphyrins and their zinc complexes, CHEMICAL PHYSICS (2004), 305 p. 13. 25.296.9 Schmidt, WG, Seino, K, Hahn, PH, Bechstedt, E, Lu, W, Wang, S, Bernholc, J, Calculation of surface optical properties: from qualitative understanding to quantitative predictions, THIN SOLID FILMS (2004), 455-56 p. 764. 25.297.10 Bernholc, J and Nardelli, MB and Lu, W and Meunier, V and Schmidt, WG and Wang, S and Zhao, Q, Large-scale Simulations of advanced materials and nanoscale devices, IEEE COMPUTER SOCIETY (2003) ISBN 0-7695-1953-9 p. 2-10. 25.298.11 Borensztein, Y and Witkowski, N and Royer, S, Isotropic and anisotropic optical reflectances of clean and hydrogen-covered Si(001)2x1 surfaces, 5TH INTERNATIONAL CONFERENCE ON OPTICS OF SURFACES AND INTERFACES (OSI-V), PROCEEDINGS (2003) ISBN 3-527-40494-5 p. 2966-2970. 25.299.12 Lu, WC, Schmidt, WG, Bernholc, J, Cycloaddition reaction versus dimer cleavage at the Si(001): C5H8 interface, PHYSICAL REVIEW B (2003), 68 p. 115327. 25.300.13 Schmidt, WG and Bechstedt, F and Bernhole, J, Terrace and step contributions to the surface optical anisotropy of Si(001), SPRINGER PROCEEDINGS IN PHYSICS (2001), 87 p. 299-300. 25.301.14 Gavrilenko, VI, Ab initio theory of second harmonic generation from semiconductor surfaces and interfaces, PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (2001), 188 p. 1267. 25.302.15 Agrawal, BK, Agrawal, S, Ab initio study of quantum confined unpassivated ultrathin Si films APPLIED PHYSICS LETTERS (2001), 79 p. 4366. 58/74 25.303.16 Hingerl, K, Balderas-Navarro, RE, Bonanni, A, Tichopadek, P, Schmidt, WG, On the origin of resonance features in reflectance difference data of silicon, APPLIED SURFACE SCIENCE (2001), 175 p. 769. 25.304.17 Gavrilenko, VI, Wu, RQ, Downer, MC, Ekerdt, JG, Lim, D, Parkinson, P, Optical second-harmonic spectra of Si(001) with H and Ge adatoms: First-principles theory and experiment, PHYSICAL REVIEW B (2001), 63 p. 165325. 25.305.18 Schmidt, WG, Bechstedt, F, Bernholc, J, Terrace and step contributions to the optical anisotropy of Si(001) surfaces, PHYSICAL REVIEW B (2001), 63 p. 045322. 25.306.19 Hwang, GS, A channel for dimer flipping on the Si(001) surface SURFACE SCIENCE (2000), 465 p. L789. 25.307.20 Schmidt, WG, Bechstedt, F, Bernholc, J, Understanding reflectance anisotropy: Surface-state signatures and bulk-related features, JOURNAL OF VACUUM SCIENCE & TECHNOLOGY B (2000), 18 p. 2215. 25.308.21 Schmidt, WG, Bernholc, J, Step-induced optical anisotropy of Si(111): H surfaces PHYSICAL REVIEW B (2000), 61 p. 7604. 25.309.1 ∗ 25.310.2 ∗ 25.311.3 ∗ 25.312.4 ∗ Palummo, M, Pulci, O, Del Sole, R, Marini, A, Schwitters, M, Haines, SR, Williams, KH, Martin, DS, Weightman, P, Butler, JE, Reflectance anisotropy spectra of the diamond (100)-(2x1) surface: Evidence of strongly bound surface state excitons, PHYSICAL REVIEW LETTERS (2005), 94 p. 087404. 25.313.5 ∗ 25.314.6 ∗ Del Sole, R and Palummo, M and Pulci, O, Theory of surface optical properties, EPIOPTICS-7, PROCEEDINGS (2004), ISBN 981-238-710-2 23 p. 1-20. 25.315.7 ∗ Silvestrelli, PL, Pulci, O, Palummo, M, Del Sole, R, Ancilotto, F, First-principles study of acetylene adsorption on Si(100): The end-bridge structure, 25.316.8 ∗ Pulci, O and Silvestrelli, PL and Palummo, M and Ancilotto, F and Del Sole, R, Ab-initio study of the adsorption of acetylene on Si(001) surface, 5TH INTERNATIONAL CONFERENCE ON OPTICS OF SURFACES AND INTERFACES (OSI-V), PROCEEDINGS (2003), ISBN 3-527-40494-5 p. 2997-3001. 25.317.9 ∗ 25.318.10 ∗ Balzarotti, A, Fanfoni, M, Patella, F, Arciprete, F, Placidi, E, Onida, G, Del Sole, R, The GaAS(001)-c(4x4) surface: a new perspective from energy loss spectra SURFACE SCIENCE (2003), 524 p. L71. 25.319.11 ∗ Onida, G, Schmidt, WG, Pulci, O, Palummo, M, Marini, A, Hogan, C, Del Sole, R, Theory for modeling the optical properties of surfaces PHYSICA 25.320.12 ∗ 25.321.13 ∗ 25.322.14 ∗ Marsili, Margherita and Witkowski, Nadine and Pulci, Olivia and Pluchery, Olivier and Silvestrelli, Pier Luigi and Del Sole, Rodolfo and Borensztein, Yves, Adsorption of small hydrocarbon molecules on Si surfaces: Ethylene on Si(001), PHYSICAL REVIEW B (2008), 77 p. 125337. Gaal-Nagy, K. and Onida, G., Ab initio calculations of the optical properties of the Si(113) 3X2 adatom-dimer-interstitial surface, PHYSICAL REVIEW B (2007), 75 p. 155331. Gatti, M, Onida, G, Effects of local fields in time-dependent density functional theory shown in oxidized silicon clusters, PHYSICAL REVIEW B (2005), 72 p. 045442. Incze, A, Del Sole, R, Onida, G, Ab initio study of reflectance anisotropy spectra of a submonolayer oxidized Si(100) surface, PHYSICAL REVIEW B (2005), 71 p. 035350. PHYSICAL REVIEW B (2003), 68 p. 235306. Hogan, C, Del Sole, R, Onida, G, Optical properties of real surfaces from microscopic calculations of the dielectric function of finite atomic slabs, PHYSICAL REVIEW B (2003), 68 p. 035405. STATUS SOLIDI A-APPLIED RESEARCH (2001), 188 p. 1233. Schmidt, WG, Bechstedt, F, Fleischer, K, Cobet, C, Esser, N, Richter, W, Bernholc, J, Onida, G, GaAs(001): Surface structure and optical properties PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (2001), 188 p. 1401. Monachesi, P, Marini, A, Onida, G, Palummo, M, Del Sole, R, All-electron versus pseudopotential calculation of optical properties: The case of GaAs, PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (2001), 184 p. 101. Palummo, M, Onida, G, Del Sole, R, Corradini, M, Reining, L, Nonlocal density scheme for electronic-structure calculations PHYSICAL REVIEW B (1999), 60 p. 11329. 25.29 Del Artı́culo 7.2.35: Visible infrared sum and difference frequency generation at adsorbate covered Au 25.323.1 Eisenthal, KB, Second harmonic spectroscopy of aqueous nano- and microparticle interfaces, CHEMICAL REVIEWS (2006), 106 p. 1462. 25.324.2 Roke, S, Kleyn, AW, Bonn, M, Femtosecond sum frequency generation at the metal-liquid interface SURFACE SCIENCE (2005), 593 p. 79. 25.325.3 Morkel, M, Unterhalt, H, Kluner, T, Rupprechter, G, Freund, HJ, Interpreting intensities in vibrational sum frequency generation (SFG) spectroscopy: CO adsorption on Pd surfaces, SURFACE SCIENCE (2005), 586 p. 146. 25.326.4 Vidal, F, Tadjeddine, A, Sum-firequency generation spectroscopy of interfaces REPORTS ON PROGRESS IN PHYSICS (2005), 68 p. 1095. 25.327.5 McGall, SJ, Davies, PB, Neivandt, DJ, Interference effects in sum frequency vibrational spectra of thin polymer films: an experimental and modeling investigation, JOURNAL OF PHYSICAL CHEMISTRY B (2004), 108 p. 16030. 25.328.6 Dreesen, L, Humbert, C, Celebi, M, Lemaire, JJ, Mani, AA, Thiry, PA, Peremans, A, Influence of the metal electronic properties on the sum-frequency generation spectra of dodecanethiol self-assembled monolayers on, Pt(111), Ag(111) Au(111) single crystals, APPLIED PHYSICS B-LASERS AND OPTICS (2002), 74 p. 621. 25.329.7 Lambert, AG, Neivandt, DJ, Briggs, AM, Usadi, EW, Davies, PB, Interference effects in sum frequency spectra from monolayers on composite dielectric/metal substrates, JOURNAL OF PHYSICAL CHEMISTRY B (2002), 106 p. 5461. 25.330.8 Humbert, C, Dreesen, L, Mani, AA, Caudano, Y, Lemaire, JJ, Thiry, PA, Peremans, A, IR-visible sum-frequency vibrational spectroscopy of Biphenyl-3 methylene thiol monolayer on gold and silver: effect of the visible, wavelength on the SFG spectrum, SURFACE SCIENCE (2002), 502 p. 203. 25.331.9 Buck, M, Himmelhaus, M, Vibrational spectroscopy of interfaces by infrared-visible sum frequency generation, JOURNAL OF VACUUM SCIENCE & TECHNOLOGY A-VACUUM SURFACES AND FILMS (2001), 19 p. 2717. 25.332.1 ∗ 25.333.2 ∗ Recamier, J and Mochan, WL and Maytorena, J, Exact non linear response of a harmonic oscillator, PROCEEDINGS OF THE SOCIETY OF Recamier, J, Mochan, WL, Maytorena, JA, Nonlinear response of a harmonic diatomic molecule: Algebraic nonperturbative calculation, PHYSICAL REVIEW A (2005), 72 p. 023805. PHOTO-OPTICAL INSTRUMENTATION ENGINEERS (SPIE) (2004), 5622 p. 513-517. 25.30 Del Artı́culo 7.2.36: Optical second harmonic generation spectroscopy of boron recunstructed Si(001) 59/74 25.334.1 Gavrilenko, V. I., Differential reflectance and second-harmonic generation of the Si/SiO2 interface from first principles, PHYSICAL REVIEW B (2008), 77 p. 155311. 25.335.2 Duerr, M. and Hoefer, U., Dissociative adsorption of molecular hydrogen on silicon surfaces, SURFACE SCIENCE REPORTS (2006), 61 p. 465-526. 25.336.3 Rumpel, A, Manschwetus, B, Lilienkamp, G, Schmidt, H, Daum, W, Polarity of space charge fields in second-harmonic generation spectra of Si(100)/SiO2 interfaces, PHYSICAL REVIEW B (2006), 74 p. 081303. 25.337.4 Sano, H, Mizutani, G, Wolf, W, Podloucky, R, Ab initio calculation of optical second harmonic generation at the rutile TiO2(110) surface, PHYSICAL REVIEW B (2004), 70 p. 125411. 25.338.5 Mishina, E, Yu, QK, Tamura, T, Sakaguchi, H, Karantonis, A, Nakabayashi, S, Kinetic profile of adsorption and self-assembling of thiophene oligomers studied by optical second harmonic generation, SURFACE SCIENCE (2003), 544 p. 269. 25.339.6 Dolgova, TV, Fedyanin, AA, Aktsipetrov, OA, dc-electric-field-induced second-harmonic interferometry of the Si(111)-SiO2 interface in Cr-SiO2-Si MOS capacitor, PHYSICAL REVIEW B (2003), 68 p. 073307. 25.340.7 Dolgova, TV, Fedyanin, AA, Aktsipetrov, OA, Marowsky, G, Optical second-harmonic interferometric spectroscopy of Si(111)-SiO2 interface in the vicinity of E-2 critical points, PHYSICAL REVIEW B (2002), 66 p. 033305. 25.341.8 Hu, SW, Kim, J, Tarakeshwar, P, Kim, KS, Insights into the nature of SiH4-BH3 complex: Theoretical investigation of new mechanistic pathways involving SiH3 center dot and BH4 center, dot radicals, JOURNAL OF PHYSICAL CHEMISTRY A (2002), 106 p. 6817. 25.342.9 Mishina, ED, Morozov, AI, Sigov, AS, Sherstyuk, NE, Aktsipetrov, OA, Lemanov, VV, Rasing, T, A study of the structural phase transition in strontium titanate single crystal by coherent and incoherent second optical harmonic generation, JOURNAL OF EXPERIMENTAL AND THEORETICAL PHYSICS (2002), 94 p. 552. 25.343.10 Fomenko, V, Bodlaki, D, Faler, C, Borguet, E, Second-harmonic generation from chemically modified Ge(111) interfaces JOURNAL OF CHEMICAL PHYSICS (2002), 116 p. 6745. 25.344.11 Mishina, ED, Ohta, N, Yu, QK, Nakabayashi, S, Dynamics of surface reconstruction and electrodeposition studied in situ by second harmonic generation, SURFACE SCIENCE (2001), 494 p. L748. 25.345.12 Simpson, GJ, New tools for surface second-harmonic generation APPLIED SPECTROSCOPY (2001), 55 p. 16A. 25.346.1 ∗ Ehlert, Robert and Kwon, Jinhee and Downer, Michael C., Optical second-harmonic and reflectance-anisotropy spectroscopy of molecular adsorption at Si(001) step-edges, PHYSICA STATUS SOLIDI C (2008), 5 p. 2551-2555. 25.347.2 ∗ 25.348.3 ∗ 25.349.4 ∗ Gavrilenko, VI, Wu, RQ, Downer, MC, Ekerdt, JG, Lim, D, Parkinson, P, Optical second-harmonic spectra of Si(001) with H and Ge adatoms: First-principles theory and experiment, PHYSICAL REVIEW B (2001), 63 p. 165325. 25.350.5 ∗ Lim, D, Downer, MC, Ekerdt, JG, Second-harmonic spectroscopy of bulk boron-doped Si(001) APPLIED PHYSICS LETTERS (2000), 77 p. 181. Gavrilenko, VI, Wu, RQ, Second harmonic generation of GaN(0001) PHYSICAL REVIEW B (2002), 65 p. 035405. Gavrilenko, VI, Ab initio theory of second harmonic generation from semiconductor surfaces and interfaces, PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (2001), 188 p. 1267. 25.31 Del Artı́culo 7.2.37: Disorder effects on second harmonic generation from one dimensional arrays of polarizable units 25.351.1 Makeev, EV, Skipetrov, SE, Second harmonic generation in suspensions of spherical particles OPTICS COMMUNICATIONS (2003), 224 p. 139. 25.352.2 Melnikov, AV, Nikulin, AA, Aktsipetrov, OA, Hyper-Rayleigh scattering by inhomogeneous thin films of Pb-x(Zr0.53Ti0.47)O-3: Disorder effects, PHYSICAL REVIEW B (2003), 67 p. 134104. 25.32 Del Artı́culo 7.2.38: Second harmonic generation from spherical particles 25.353.1 Schaich, W. L., Formation of Pt islets on facets of Ru nanoparticles: First-principles study, PHYSICAL REVIEW B (2008), 79 p. 195416. 25.354.2 Dadap, Jerry Icban, Optical second-harmonic scattering from cylindrical particles, PHYSICAL REVIEW B (2008), 78 p. 205322. 25.355.3 Russier-Antoine, Isabelle and Bachelier, Guillaume and Sabloniere, Virginie and Duboisset, Julien and Benichou, Emmanuel and Jonin, Christian and Bertorelle, Franck and Brevet, Pierre-Francois, Surface heterogeneity in Au-Ag nanoparticles probed by hyper-Rayleigh scattering, PHYSICAL REVIEW B (2008), 78 p. 035436. 25.356.4 Bachelier, Guillaume and Russier-Antoine, Isabelle and Benichou, Emmanuel and Jonin, Christian and Brevet, Pierre-Francois, JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B (2008), 25 p.955-960. 25.357.5 Adles, E. J. and Aspnes, D. E., The anisotropic bond model of nonlinear optics, PHYSICA STATUS SOLIDI A (2008), 205 p. 728-731. 25.358.6 Adles, E. J. and Aspnes, D. E., Application of the anisotropic bond model to second-harmonic generation from amorphous media, PHYSICAL REVIEW B (2008), 77 p. 165102. 25.359.7 Kozyreff, G. and Juarez, J. L. Dominguez and Martorell, Jordi, Whispering-gallery-mode phase matching for surface second-order nonlinear optical processes in spherical microresonators, PHYSICAL REVIEW A (2008), 77 p. 043817. 25.360.8 Xu, T. and Jiao, X. and Zhang, G. P. and Blair, S., Second-harmonic emission from sub-wavelength apertures: Effects of aperture symmetry and lattice arrangement, OPTICS EXPRESS (2007), 15 p. 13894-13906. 25.361.9 Remita, S. and Fontaine, P. and Lacaze, E. and Borensztein, Y. and Sellame, H. and Farha, R. and Rochas, C. and Goldmann, M., X-ray radiolysis induced formation of silver nano-particles: A SAXS and UV-visible absorption spectroscopy study, NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION B (2007), 263 p. 436-440. 25.362.10 Finazzi, M. and Biagioni, P. and Celebrano, M. and Duo, L., Selection rules for second-harmonic generation in nanoparticles, PHYSICAL REVIEW B (2007), 76 p. 125414. 25.363.11 de Beer, Alex G. F. and Roke, Sylvie, Sum frequency generation scattering from the interface of an isotropic particle: Geometrical and chiral effects, PHYSICAL REVIEW B (2007), 75 p. 245438. 25.364.12 Russier-Antoinc, I. and Benichou, E. and Bachelier, G. and Jonin, C. and Brevet, P. F., Multipolar contributions of the second harmonic generation from silver and gold nanoparticles, JOURNAL OF PHYSICAL CHEMISTRY C (2007), 111 p. 9044-9048. 25.365.13 Schneider, L. and Schmid, H. J. and Peukert, W., Influence of particle size and concentration on the second-harmonic signal generated at colloidal surfaces, APPLIED PHYSICS B (2007), 87 p. 333-339. 25.366.14 Schneider, Lars and Peukert, Wolfgang, Review: Second harmonic generation spectroscopy as a method for in situ and online characterization of particle surface properties, PARTICLE & PARTICLE SYSTEMS CHARACTERIZATION (2007), 23 p. 351-359. 60/74 25.367.15 Nappa, Jerome and Revillod, Guillaume and Russier-Antoine, Isabelle and Jonin, Christian and Benichou, Emmanuel and Brevet, Pierre-Francois, Relative magnitude of dipolar and quadrupolar contributions to the second harmonic generation from small gold metallic nanoparticles, PROCEEDINGS OF THE SOCIETY OF PHOTO-OPTICAL INSTRUMENTATION ENGINEERS (2006), 6258 p. O2580. 25.368.16 Nappa, J. and Russier-Antoine, I. and Benichou, E. and Jonin, Ch. and Brevet, P. F., Second harmonic generation from small gold metallic particles: From the dipolar to the quadrupolar response, JOURNAL OF CHEMICAL PHYSICS (2006), 125 p. 184712. 25.369.17 Pang, CP, Lue, JT, Linear and nonlinear optical properties of hydrated and dehydrated silica micro-spheres under an electric bias, EUROPEAN PHYSICAL JOURNAL B (2006), 51 p. 593. 25.370.18 Canfield, BK, Kujala, S, Jefimovs, K, Svirko, Y, Turunen, J, Kauranen, M, Amacroscopic formalism to describe the second-order nonlinear optical response of nanostructures, JOURNAL OF OPTICS A-PURE AND APPLIED OPTICS (2006), 8 p. S278. 25.371.19 Deng, XY, Wang, XJ, Liu, HP, Zhuang, ZF, Guo, ZY, Simulation study of second-harmonic microscopic imaging signals through tissue-like turbid media, JOURNAL OF BIOMEDICAL OPTICS (2006), 11 p. 024013. 25.372.20 Eisenthal, KB, Second harmonic spectroscopy of aqueous nano- and microparticle interfaces, CHEMICAL REVIEWS (2006), 106 p. 1462. 25.373.21 Shan, J, Dadap, JI, Stiopkin, I, Reider, GA, Heinz, TF, Experimental study of optical second-harmonic scattering from spherical nanoparticles, PHYSICAL REVIEW A (2006), 73 p. 023819. 25.374.22 Shcheslavskiy, VI, Saltiel, SM, Faustov, A, Petrov, GI, Yakovlev, VV, Third-harmonic Rayleigh scattering: theory and experiment JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B-OPTICAL PHYSICS (2005), 22 p. 2402. 25.375.23 Gao, L, Yu, KW, Second- and third-harmonic generation in random composites of graded spherical particles, PHYSICAL REVIEW B (2005), 72 p. 075111. 25.376.24 Sun, L, Figliozzi, P, An, YQ, Downer, MC, Nonresonant quadrupolar second-harmonic generation in isotropic solids by use of two orthogonally polarized laser beams, OPTICS LETTERS (2005), 30 p. 2287. 25.377.25 Neacsu, CC, Reider, GA, Raschke, MB, Second-harmonic generation from nanoscopic metal tips: Symmetry selection rules for single asymmetric nanostructures, PHYSICAL REVIEW B (2005), 71 p. 201402. 25.378.26 Nappa, J, Revillod, G, Russier-Antoine, I, Benichou, E, Jonin, C, Brevet, PF, Electric dipole origin of the second harmonic generation of small metallic particles, PHYSICAL REVIEW B (2005), 71 p. 165407. 25.379.27 Moran, AM, Sung, JH, Hicks, EM, Van Duyne, RP, Spears, KG, Second harmonic excitation spectroscopy of silver nanoparticle arrays JOURNAL OF PHYSICAL CHEMISTRY B (2005), 109 p. 4501. 25.380.28 Airola, M, Liu, Y, Blair, S, Second-harmonic generation from an array of sub-wavelength metal apertures, JOURNAL OF OPTICS A-PURE AND APPLIED OPTICS (2005), 7 p. S118. 25.381.29 Airola, M and Blair, S, Second-harmonic generation from an array of sub-wavelength metal apertures, PROCEEDINGS OF THE SOCIETY OF PHOTO-OPTICAL INSTRUMENTATION ENGINEERS (SPIE) (2005), 5736 p. 81-86. 25.382.30 Wang, G and Zhang, Y and Cui, YP and Duan, MY and Liu, M, Size dependence of the Behavior of Hyper-Rayleigh scattering for silver nanoparticle, PROCEEDINGS OF THE SOCIETY OF PHOTO-OPTICAL INSTRUMENTATION ENGINEERS (SPIE) (2005), 5646 p. 51-57. 25.383.31 Mendez, ER and Valencia, CI, Second harmonic generation by random particle systems, AIP CONFERENCE PROCEEDINGS (2005), 759 p. 52-61. 25.384.32 Wang, G, Zhang, Y, Cui, YP, Duan, M, Liu, M, Study on the behavior of Hyper-Rayleigh scattering for silver nanoparticles with aggregation effects, JOURNAL OF PHYSICAL CHEMISTRY B (2005), 109 p. 1067. 25.385.33 Pavlyukh, Y, Hubner, W, Nonlinear Mie scattering from spherical particles PHYSICAL REVIEW B (2004), 70 p. 245434. 25.386.34 Thantu, N, Second harmonic generation and two-photon luminescence upconversion in glasses doped with ZnSe nanocrystalline quantum dots, JOURNAL OF LUMINESCENCE (2005), 111 p. 17. 25.387.35 Wang, G, Duan, MY, Cui, YP, Zhang, Y, Liu, M, Study on the influence on the characteristic of the second-order nonlinear optics by using aggregation of silver nanoparticles, ACTA PHYSICA SINICA (2005), 54 p. 144. 25.388.36 Abid, JP, Nappa, J, Girault, HH, Brevet, PF, Pure surface plasmon resonance enhancement of the first hyperpolarizability of gold core-silver shell nanoparticles, JOURNAL OF CHEMICAL PHYSICS (2004), 121 p. 12577. 25.389.37 Bernal, R, Maytorena, JA, Second harmonic generation from centrosymmetric thin films by a focused beam with arbitrary transverse structure, PHYSICAL REVIEW B (2004), 70 p. 125420. 25.390.38 Dadap, JI, Shan, J, Heinz, TF, Theory of optical second-harmonic generation from a sphere of centrosymmetric material: small-particle limit, JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B-OPTICAL PHYSICS (2004), 21 p. 1328. 25.391.39 Russier-Antoine, I, Jonin, C, Nappa, J, Benichou, E, Brevet, PF, Wavelength dependence of the hyper Rayleigh scattering response from gold nanoparticles, JOURNAL OF CHEMICAL PHYSICS (2004), 120 p. 10748. 25.392.40 Downer, MC and Figliozzi, PC and Jiang, Y and Sun, L and Mattern, B and White, CW and Withrow, SP, Optical second-harmonic generation from silicon nanocrystals, PROCEEDINGS OF THE SOCIETY OF PHOTO-OPTICAL INSTRUMENTATION ENGINEERS (SPIE) (2003), 5223 p. 1-8. 25.393.41 Makeev, EV, Skipetrov, SE, Second harmonic generation in suspensions of spherical particles OPTICS COMMUNICATIONS (2003), 224 p. 139. 25.394.42 Jiang, Y, Sun, L, Downer , MC, Second-harmonic spectroscopy of two-dimensional Si nanocrystal layers embedded in SiO2 films, APPLIED PHYSICS LETTERS (2002), 81 p. 3034. 25.395.43 Jiang, Y, Wilson, PT, Downer, MC, White, CW, Withrow, SP, Second-harmonic generation from silicon nanocrystals embedded in SiO2 APPLIED PHYSICS LETTERS (2001), 78 p. 766. 25.396.1 ∗ 25.397.2 ∗ Mochan, WL, SHG from bulk and surface of nanoparticle composites, PHYSICA STATUS SOLIDI C (2005), 2 p. 4062-4066. Recamier, J, Mochan, WL, Maytorena, JA, Nonlinear response of a harmonic diatomic molecule: Algebraic nonperturbative calculation, PHYSICAL REVIEW A (2005), 72 p. 023805. 25.33 Del Artı́culo 7.2.39: Polarizable bond model for optical spectra of Si(100) reconstructed surfaces 25.398.1 McGilp, J. F., Using steps at the Si-SiO2 interface to test simple bond models of the optical second-harmonic response, JOURNAL OF PHYSICSCONDENSED MATTER (2007), 19 p. 016006. 25.399.2 McGlip, JF, Carroll, L, Bulk and interface contributions to the optical second-harmonic response of native-oxide-covered vicinal Si(111), PHYSICA STATUS SOLIDI B-BASIC SOLID STATE PHYSICS (2005), 242 p. 3012. 25.400.3 Hogan, C, Del Sole, R, Optical properties of the GaAs(001)-c(4x4) surface: direct analysis of the surface dielectric function, PHYSICA STATUS SOLIDI B-BASIC SOLID STATE PHYSICS (2005), 242 p. 3040. 61/74 25.401.4 Leitsmann, R, Schmidt, WG, Hahn, PH, Bechstedt, F, Second-harmonic polarizability including electron-hole attraction from band-structure theory, PHYSICAL REVIEW B (2005), 71 p. 195209. 25.402.5 Schmidt, WG, Seino, K, Hahn, PH, Bechstedt, E, Lu, W, Wang, S, Bernholc, J, Calculation of surface optical properties: from qualitative understanding to quantitative predictions, THIN SOLID FILMS (2004), 455-56 p. 764. 25.403.6 McGilp, JF and Carroll, L, Bond hyperpolarizabilities - SHG simplified?, PHYSICA STATUS SOLIDI B-BASIC RESEARCH (2003), 240 p. 3060-3064. 25.404.7 Aspnes, DE, Hansen, JK, Peng, HJ, Powell, GD, Wang, JFT, Simplified bond-hyperpolarizability model of second- and fourth-harmonic generation: application to Si-SiO2 interfaces, PHYSICA STATUS SOLIDI B-BASIC RESEARCH (2003), 240 p. 509-517. 25.405.8 Wang, JFT, Powell, GD, Johnson, RS, Lucovsky, G, Aspnes, DE, Simplified bond-hyperpolarizability model of second harmonic generation: Application to Si-dielectric interfaces, JOURNAL OF VACUUM SCIENCE & TECHNOLOGY B (2002), 20 p. 1699. 25.406.9 Powell, GD, Wang, JF, Aspnes, DE, Simplified bond-hyperpolarizability model of second harmonic generation PHYSICAL REVIEW B (2002), 65 p. 205320. 25.407.10 S. Galamic-Mulaomerovic, C.D. Hogan, C.H. Patterson Eigenfunctions of the Inverse Dielectric Functions and Response Functions of Silicon and Argon, physica status solidi (a) (2001), 188 p. 1291. 25.34 Del Artı́culo 7.2.41: Ab initio calculation of second harmonic generation at the clean Si(100) surface 25.408.1 Gavrilenko, V. I., Differential reflectance and second-harmonic generation of the Si/SiO2 interface from first principles, PHYSICAL REVIEW B (2008), 77 p. 155311. 25.409.2 Ren, CY, Chiou, SH, Choisnet, J, First-principles calculations of the electronic band structure of In4Sn3O12 and In5SnSbO12, JOURNAL OF APPLIED PHYSICS (2006), 99 p. 023706. 25.410.3 Meier, T, Reichelt, M, Koch, SW, Hofer, U, Femtosecond time-resolved five-wave mixing at silicon surfaces JOURNAL OF PHYSICS-CONDENSED MATTER (2005), 17 p. S221. 25.411.4 Durr, M, Hofer, U, Molecular beam investigation of hydrogen dissociation on Si(001) and Si(111) surfaces, JOURNAL OF CHEMICAL PHYSICS (2004), 121 p. 8058. 25.412.5 Sano, H, Mizutani, G, Wolf, W, Podloucky, R, Ab initio calculation of optical second harmonic generation at the rutile TiO2(110) surface, PHYSICAL REVIEW B (2004), 70 p. 125411. 25.413.6 Ren, CY, Chiou, SH, Hsue, CS, Ga-doping effects on electronic and structural properties of wurtzite ZnO, PHYSICA B-CONDENSED MATTER (2004), 349 p. 136. 25.414.7 Voelkmann, C, Reichelt, M, Meier, T, Koch, SW, Hofer, U, Five-wave-mixing spectroscopy of ultrafast electron dynamics at a Si(001) surface, PHYSICAL REVIEW LETTERS (2004), 92 p. 127405. 25.415.8 Pedersen, K and Morgen, P, Second-harmonic generation spectroscopy on reconstructed Si(111) surfaces, 5TH INTERNATIONAL CONFERENCE ON OPTICS OF SURFACES AND INTERFACES (OSI-V), PROCEEDINGS (2003), ISBN 3-527-40494-5 p. 3065-3069. 25.416.9 Gavrilenko, VI, Ab initio theory of second harmonic generation from semiconductor surfaces and interfaces, PHYSICA STATUS SOLIDI A-APPLIED RESEARCH (2001), 188 p. 1267. 25.417.1 ∗ Hogan, C, Del Sole, R, Onida, G, Optical properties of real surfaces from microscopic calculations of the dielectric function of finite atomic slabs, PHYSICAL REVIEW B (2003), 68 p. 035405. 25.35 Del Artı́culo 7.2.43: Optical second harmonic spectroscopy of semiconductor surfaces: advances in microscopic understanding 25.418.1 Dadap, Jerry Icban, Optical second-harmonic scattering from cylindrical particles, PHYSICAL REVIEW B (2008), 78 p. 205322. 25.419.2 Gavrilenko, V. I., Differential reflectance and second-harmonic generation of the Si/SiO2 interface from first principles, PHYSICAL REVIEW B (2008), 77 p. 155311. 25.420.3 Finazzi, M. and Biagioni, P. and Celebrano, M. and Duo, L., Selection rules for second-harmonic generation in nanoparticles, PHYSICAL REVIEW B (2007), 76 p. 125414. 25.421.4 Foerstendorf, Harald and Seidel, Wolfgang and Heim, Karsten and Bernhard, Gert, Identification of actinide molecule complexes: A new vibrational spectroscopic approach at the free-electron laser facility FELBE, JOURNAL OF NUCLEAR MATERIALS (2007), 366 p. 248-255. 25.422.5 Kolasinski, Kurt W. and DeWitt, Kristy M. and Harrison, Ian, Sum frequency generation from planar and porous silicon in contact with liquids, PHYSICA STATUS SOLIDI A (2007), 204 p. 1356-1361. 25.423.6 Duerr, M. and Hoefer, U., Dissociative adsorption of molecular hydrogen on silicon surfaces, SURFACE SCIENCE REPORTS (2006), 61 p. 465-526. 25.424.7 Kolasinski, K. W. and Harrison, I. and Gavrilenko, A. V. and Bonner, C. E. and Gavrilenko, V. I., Characterization of chemisorption on porous silicon by Sum Frequency Generation, PROCEEDINGS OF THE SOCIETY OF PHOTO-OPTICAL INSTRUMENTATION ENGINEERS (SPIE) (2006), 6320 p. Q3200. 25.425.8 McClelland, Arthur and Fomenko, Vasiliy and Borguet, Eric, Ultrafast hot-carrier dynamics at chemically modified Ge interfaces probed by SHG, JOURNAL OF PHYSICAL CHEMISTRY B (2006), 110 p. 19784-19787. 25.426.9 Leitsmann, R, Schmidt, WG, Hahn, PH, Bechstedt, F, Second-harmonic polarizability including electron-hole attraction from band-structure theory, PHYSICAL REVIEW B (2005), 71 p. 195209. 25.427.10 Mcgilp, JF, Optical second harmonic generation and the characterisation of low dimensional nanostructures on planar silicon, EPIOPTICS-7, PROCEEDINGS (2004), ISBN 981-238-710-2 p. 62-79. 25.428.11 Raschke, MB, Shen, YR, Nonlinear optical spectroscopy of solid interfaces CURRENT OPINION IN SOLID STATE & MATERIALS SCIENCE (2004), 8 p. 343. 25.429.12 Fomenko, V, Gusev, EP, Borguet, E, Optical second harmonic generation studies of ultrathin high-k dielectric stacks, JOURNAL OF APPLIED PHYSICS (2005), 97 p. 083711. 25.430.13 Mcgilp, JF, Optical second harmonic generation and the characterisation of low dimensional nanostructures on planar silicon, SCIENCE AND CULTURE SERIES: PHYSICS (2004), 23 p. 62-79. 25.431.14 Schmidt, WG, Seino, K, Hahn, PH, Bechstedt, E, Lu, W, Wang, S, Bernholc, J, Calculation of surface optical properties: from qualitative understanding to quantitative predictions, THIN SOLID FILMS (2004), 455-56 p. 764. 62/74 25.432.15 McClelland, A, Fomenko, V, Borguet, E, Ultrafast time-evolution of the nonlinear susceptibility of hot carriers at the Ge(111)-GeO2 interface as probed by SHG, JOURNAL OF PHYSICAL CHEMISTRY B (2004), 108 p. 3789. 25.433.16 Bodlaki, D, Yamamoto, H, Waldeck, DH, Borguet, E, Ambient stability of chemically passivated germanium interfaces SURFACE SCIENCE (2003), 543 p. 63. 25.434.17 Fomenko, V, Borguet, E, Combined electron-hole dynamics at UV-irradiated ultrathin Si-SiO2 interfaces probed by second harmonic generation, PHYSICAL REVIEW B (2003), 68 p. 081301. 25.435.18 Bodlaki, D, Borguet, E, Dynamics and second-order nonlinear optical susceptibility of photoexcited carriers at Si(111) interfaces, APPLIED PHYSICS LETTERS (2003), 83 p. 2357. 25.436.19 Mitchell, SA, Photooxidation of hydrogen-terminated Si(111) surfaces studied by optical second harmonic generation, JOURNAL OF PHYSICAL CHEMISTRY B (2003), 107 p. 9388. 25.437.20 Fomenko, V, Bodlaki, D, Faler, C, Borguet, E, Second-harmonic generation from chemically modified Ge(111) interfaces JOURNAL OF CHEMICAL PHYSICS (2002), 116 p. 6745. 25.438.21 Pickering, C, Optical characterization techniques for process monitoring SURFACE AND INTERFACE ANALYSIS (2001), 31 p. 909. 25.439.22 Pemble, ME, NESSPIOM - Network for enhanced semiconductor surface processing through in situ optical monitoring, SURFACE AND INTERFACE ANALYSIS (2001), 31 p. 1012. 25.440.1 ∗ 25.441.2 ∗ Kwon, J and Downer, MC, Simplified bond model of spectroscopic SHG and RAS of oxidized and reconstructed vicinal Si(001), PHYSICA STATUS SOLIDI C (2005), 2 p. 3973-3977. Mochan, WL, SHG from bulk and surface of nanoparticle composites, Physica Status Solidi C (2005), 2 p. 4062-4066. 25.36 Del Artı́culo 7.2.44: Optical second harmonic spectroscopy of silicon surfaces, interfaces and nanocrystals 25.442.1 Peng, HJ, Aspnes, DE, Calculation of bulk third-harmonic generation from crystalline Si with the simplified bond hyperpolarizability model, PHYSICAL REVIEW B (2004), 70 p. 165312. 25.443.1 ∗ Price, J and Diebold, AC and Carriles, R and An, YQ and Kwon, JH and Downer, MC, Complimentary optical metrology techniques used for 25.444.2 ∗ characterization of high-K gate dielectrics, Characterization and Metrology for ULSI Technology (2005), 788 p. 129-135. Wilson, PT, Jiang, Y, Carriles, R, Downer, MC, Second-harmonic amplitude and phase spectroscopy by use of broad-bandwidth femtosecond pulses, JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B-OPTICAL PHYSICS (2003), 20 p. 2548. 25.37 Del Artı́culo 7.2.47: Surface second harmonic generation from Si(111)(1×1)H: Theory versus Experiment 25.445.1 Duerr, M. and Hoefer, U., Dissociative adsorption of molecular hydrogen on silicon surfaces, SURFACE SCIENCE REPORTS (2006), 61 p. 465-526. 25.446.2 Sano, H, Mizutani, G, Wolf, W, Podloucky, R, Ab initio calculation of optical second harmonic generation at the rutile TiO2(110) surface, PHYSICAL REVIEW B (2004), 70 p. 125411. 25.447.3 Schmidt, WG, Seino, K, Hahn, PH, Bechstedt, E, Lu, W, Wang, S, Bernholc, J, Calculation of surface optical properties: from qualitative understanding to quantitative predictions, THIN SOLID FILMS (2004), 455-56 p. 764. 25.38 Del Artı́culo 7.2.48: Model for the effects of surface disorder on reflectance anisotropy spectroscopy 25.448.1 ∗ Fleischer, K, Bussetti, G, Goletti, C, Richter, W, Chiaradia, P, Optical anisotropy of Cs nanostructures on III-V(110) surfaces JOURNAL OF PHYSICS-CONDENSED MATTER (2004), 16 p. S4353. 25.449.2 ∗ Herrmann, T, Gensch, M, Lee, MJG, Shkrebtii, AI, Esser, N, Richter, W, Hofmann, P, Optical reflectance anisotropy of Al(110): Experiment and ab initio calculation, PHYSICAL REVIEW B (2004), 69 p. 165406. 25.39 Del Artı́culo 7.2.49: Layer by layer analysis of surface reflectance anisotropy in semiconductors 25.450.1 Gaal-Nagy, K. and Onida, G., Ab initio calculations of the optical properties of the Si(113) 3X2 adatom-dimer-interstitial surface, PHYSICAL REVIEW B (2007), 75 p. 155331. 25.451.2 Schmidt, WG, Calculation of reflectance anisotropy for semiconductor surface exploration, PHYSICA STATUS SOLIDI B (2005), 242 p. 2751-2764. 25.452.3 Incze, A, Del Sole, R, Onida, G, Ab initio study of reflectance anisotropy spectra of a submonolayer oxidized Si(100) surface, PHYSICAL REVIEW B (2005), 71 p. 035350. 25.453.1 ∗ Schmidt, WG, Calculation of reflectance anisotropy for semiconductor surface exploration PHYSICA STATUS SOLIDI B (2005), 242 p. 2751-2764. 25.40 Del Artı́culo 7.2.50: Second harmonic generation in arrays of spherical particles 25.454.1 Schaich, W. L., Formation of Pt islets on facets of Ru nanoparticles: First-principles study, PHYSICAL REVIEW B (2008), 78 p. 195416. 25.455.2 Dadap, Jerry Icban, Optical second-harmonic scattering from cylindrical particles, PHYSICAL REVIEW B (2008), 78 p. 205322. 25.456.3 Wirth, A. and Wel, J. and Gielis, J. J. H. and Figliozzi, P. and Rafaelsen, J. and An, Y. Q. and Downer, M. C., Second-harmonic spectroscopy of Si nanocrystals embedded in silica, PHYSICA STATUS SOLIDI C (2008), 5 p. 2662-2666. 25.457.4 Adles, E. J. and Aspnes, D. E., The anisotropic bond model of nonlinear optics, PHYSICA STATUS SOLIDI A (2008), 205 p. 728-731. 25.458.5 Adles, E. J. and Aspnes, D. E., Application of the anisotropic bond model to second-harmonic generation from amorphous media, PHYSICAL REVIEW B (2008), 77 p. 165102. 63/74 25.459.6 Finazzi, M. and Biagioni, P. and Celebrano, M. and Duo, L., Selection rules for second-harmonic generation in nanoparticles, PHYSICAL REVIEW B (2007), 76 p. 125414. 25.460.7 de Beer, Alex G. F. and Roke, Sylvie, Sum frequency generation scattering from the interface of an isotropic particle: Geometrical and chiral effects, PHYSICAL REVIEW B (2007), 75 p. 245438. 25.461.8 Schneider, L. and Schmid, H. J. and Peukert, W., Influence of particle size and concentration on the second-harmonic signal generated at colloidal surfaces, APPLIED PHYSICS B (2007), 87 p. 333-339. 25.462.9 Deng, XY, Wang, XJ, Liu, HP, Zhuang, ZF, Guo, ZY, Simulation study of second-harmonic microscopic imaging signals through tissue-like turbid media, JOURNAL OF BIOMEDICAL OPTICS (2006), 11 p. 024013. 25.463.10 Shan, J, Dadap, JI, Stiopkin, I, Reider, GA, Heinz, TF, Experimental study of optical second-harmonic scattering from spherical nanoparticles, PHYSICAL REVIEW A (2006), 73 p. 023819. 25.464.11 Sun, L, Figliozzi, P, An, YQ, Downer, MC, Nonresonant quadrupolar second-harmonic generation in isotropic solids by use of two orthogonally polarized laser beams, OPTICS LETTERS (2005), 30 p. 2287. 25.465.12 Pavlyukh, Y, Hubner, W, Nonlinear Mie scattering from spherical particles PHYSICAL REVIEW B (2004), 70 p. 245434. 25.466.13 Thantu, N, Second harmonic generation and two-photon luminescence upconversion in glasses doped with ZnSe nanocrystalline quantum dots, JOURNAL OF LUMINESCENCE (2005), 111 p. 17. 25.467.14 Dadap, JI, Shan, J, Heinz, TF, Theory of optical second-harmonic generation from a sphere of centrosymmetric material: small-particle limit, JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B-OPTICAL PHYSICS (2004), 21 p. 1328. 25.468.1 ∗ Recamier, J, Mochan, WL, Maytorena, J, Nonlinear response of a deformed oscillator INTERNATIONAL JOURNAL OF QUANTUM CHEMISTRY (2005), 105 p. 794. 25.469.2 ∗ Bernal, R, Maytorena, JA, Second harmonic generation from centrosymmetric thin films by a focused beam with arbitrary transverse structure, PHYSICAL REVIEW B (2004), 70 p. 125420. 25.41 Del Artı́culo 7.2.51: Second harmonic generation in the scattering of light by two dimensional particles 25.470.1 Dadap, Jerry Icban, Optical second-harmonic scattering from cylindrical particles, PHYSICAL REVIEW B (2008), 78 p. 205322. 25.471.2 Kujala, Sami and Canfield, Brian K. and Kauranen, Martti and Svirko, Yuri and Turunen, Jari, Multipolar analysis of second-harmonic radiation from gold nanoparticles, OPTICS EXPRESS (2008), 16 p. 17196-17208. 25.472.3 Kozyreff, G. and Juarez, J. L. Dominguez and Martorell, Jordi, Whispering-gallery-mode phase matching for surface second-order nonlinear optical processes in spherical microresonators, PHYSICAL REVIEW A (2008), 77 p. 043817. 25.473.4 Giannini, Vincenzo and Sanchez-Gil, Jose A., Calculations of light scattering from isolated and interacting metallic nanowires of arbitrary cross section by means of Green’s theorem surface intergral equations in parametric form, JOURNAL OF THE OPTICAL SOCIETY OF AMERICA A (2007), 24 p. 2822-2830. 25.474.5 Kujala, Sami and Canfield, Brian K. and Kauranen, Martti and Svirko, Yuri and Turunen, Jari, Multipole interference in the second-harmonic optical radiation from gold nanoparticles, PHYSICAL REVIEW LETTERS (2007), 98 p. 167403. 25.475.6 Liaw, JW, Simulation of surface plasmon resonance of metallic nanoparticles by the boundaryelement method, JOURNAL OF THE OPTICAL SOCIETY OF AMERICA A-OPTICS IMAGE SCIENCE AND (2006), 23 p. 108. 25.476.1 ∗ Giannini, V. and Sanchez-Gil, J. A. and Garcia-Ramos, J. V. and Mendez, E. R., Electromagnetic model and calculations of the surface-enhanced Raman-shifted emission from Langmuir-Blodgett films on metal nanostructures, JOURNAL OF CHEMICAL PHYSICS (2007), 127 p. 044702. 25.477.2 ∗ 25.478.3 ∗ Mendez, ER and Valencia, CI, Second harmonic generation by random particle systems, AIP CONFERENCE PROCEEDINGS (2005), 759 p. 52-61. Giannini, V. and Sanchez-Gil, J. A. and Garcia-Ramos, J. V. and Mendez, E. R., Collective electromagnetic emission from molecular layers on metal nanostructures mediated by surface plasmons, PHYSICAL REVIEW B (2007), 75 p. 235447. 25.42 Del Artı́culo 7.2.52: Second harmonic generation from a collection of nanoparticles 25.479.1 Kujala, Sami and Canfield, Brian K. and Kauranen, Martti and Svirko, Yuri and Turunen, Jari, Multipolar analysis of second-harmonic radiation from gold nanoparticles, OPTICS EXPRESS (2008), 16 p. 17196-17208. 25.480.2 Kujala, Sami and Canfield, Brian K. and Kauranen, Martti and Svirko, Yuri and Turunen, Jari, Multipole interference in the second-harmonic optical radiation from gold nanoparticles, PHYSICAL REVIEW LETTERS (2007), 98 p. 167403. 25.481.3 Dadap, JI, Shan, J, Heinz, TF, Theory of optical second-harmonic generation from a sphere of centrosymmetric material: small-particle limit, JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B-OPTICAL PHYSICS (2004), 21 p. 1328. 25.43 Del Artı́culo 7.2.55: Second harmonic generation in the scattering of light by an infinite cylinder 25.482.1 Dadap, Jerry Icban, Optical second-harmonic scattering from cylindrical particles, PHYSICAL REVIEW B (2008), 78 p. 205322. 25.483.2 Kozyreff, G. and Juarez, J. L. Dominguez and Martorell, Jordi, Whispering-gallery-mode phase matching for surface second-order nonlinear optical processes in spherical microresonators, PHYSICAL REVIEW A (2008), 77 p. 043817. 25.484.3 Li, S. and Li, Y. and Zhang, H. and Liu, S. and Zhou, G. and Han, Y. and Hou, L., Influence of interstitial air holes in index-guiding photonic crystal fibers on their basic properties, APPLIED PHYSICS B (2007), 87 p. 71-74. 25.485.4 Centeno, Emmanuel and Felbacq, Didier, Second-harmonic emission in two-dimensional photonic crystals, JOURNAL OF THE OPTICAL SOCIETY OF AMERICA B (2006), 23 p. 2257-2264. 25.486.1 ∗ Mendez, ER and Valencia, CI, Second harmonic generation by random particle systems, AIP CONFERENCE PROCEEDINGS (2005), 759 p. 52-61. 25.44 Del Artı́culo 7.2.56: Polarizable dipole models for reflectance anisotropy spectroscopy: a review 64/74 25.487.1 Bussetti, G, Corradini, C, Goletti, C, Chiaradia, P, Russ, M, Paolesse, R, Di Natale, C, D’Amico, A, Valli, L, Optical anisotropy and gas sensing properties of ordered porphyrin films PHYSICA STATUS SOLIDI B-BASIC SOLID STATE PHYSICS (2005), 242 p. 2714. 25.488.1 ∗ Vazquez-Nava, R. A. and Arzate, N. and Mejia, J. E. and Mochan, W. L., Dipole model for the linear response of adsorbed overlayers, PHYSICA STATUS SOLIDI C (2008), 5 p. 2578-2581. 25.45 Del Artı́culo 7.2.58: Spin Orbit effects on reflectance anisotropy spectroscopy 25.489.1 Lopez-Lozano, X, Pulci, O, Noguez, C, Fleischer, K, Del Sole, R, Richter, W, Electronic structure and reflectance anisotropy spectrum of InAs(110) PHYSICAL REVIEW B (2005), 71 p. 125337. 25.490.1 ∗ Vazquez-Nava, R. A. and Arzate, N. and Mejia, J. E. and Mochan, W. L., Dipole model for the linear response of adsorbed overlayers, PHYSICA STATUS SOLIDI C (2008), 5 p. 2578-2581. 25.46 Del Artı́culo 7.2.59: Single and enhanced two beam second harmonic generation from silicon nanocrystals by use of spatially inhomogeneous femtosecond pulses 25.491.1 Murzina, T. V. and Kolmychek, I. A. and Maidykovski, A. I. and Nikulin, A. A. and Sychev, E. Yu. and Aktsipetrov, O. A., Second- and third-harmonic generation and hyper-Rayleigh scattering in porous-silicon-based photonic microcavities, OPTICS LETTERS (2008), 33 p. 2581-2583. 25.492.2 Gielis, J. J. H. and Gevers, P. M. and Aarts, I. M. P. and van de Sanden, M. C. M. and Kessels, W. M. M., Optical second-harmonic generation in thin film systems, JOURNAL OF VACUUM SCIENCE & TECHNOLOGY A (2008), 26 p. 1519-1537. 25.493.3 Adles, E. J. and Aspnes, D. E., The anisotropic bond model of nonlinear optics, PHYSICA STATUS SOLIDI A (2008), 205 p. 728-731. 25.494.4 Adles, E. J. and Aspnes, D. E., Application of the anisotropic bond model to second-harmonic generation from amorphous media, PHYSICAL REVIEW B (2008), 77 p. 165102. 25.495.5 Finazzi, M. and Biagioni, P. and Celebrano, M. and Duo, L., Selection rules for second-harmonic generation in nanoparticles, PHYSICAL REVIEW B (2007), 76 p. 125414. 25.496.6 Rodriguez, Francisco J. and Wang, Fu Xiang and Canfield, Brian K. and Cattaneo, Stefano and Kauranen, Martti, Multipolar tensor analysis of second-order nonlinear optical response of surface and bulk of glass, OPTICS EXPRESS (2007), 15 p. 8695-8701. 25.497.7 de Beer, Alex G. F. and Roke, Sylvie, Sum frequency generation scattering from the interface of an isotropic particle: Geometrical and chiral effects, PHYSICAL REVIEW B (2007), 75 p. 245438. 25.498.8 Oliver, A. and Reyes-Esqueda, J. A. and Cheang-Wong, J. C. and Roman-Velazquez, C. E. and Crespo-Sosa, A. and Rodriguez-Fernandez, L. and Seman, J. A. and Noguez, Cecilia, Controlled anisotropic deformation of Ag nanoparticles by Si ion irradiation, PHYSICAL REVIEW B (2006), 74 p. 245425. 25.499.9 Brewer, J. and Schiek, M. and Luetzen, A. and Al-Shamery, K. and Rubahn, H. -G., Nanofiber frequency doublers, NANO LETTERS (2006), 6 p. 2656-2659. 25.500.10 Zhang, WK, Wang, HF, Zheng, DS, Quantitative measurement and interpretation of optical second harmonic generation from molecular interfaces, PHYSICAL CHEMISTRY CHEMICAL PHYSICS (2006), 8 p. 4041. 25.501.11 Shan, J, Dadap, JI, Stiopkin, I, Reider, GA, Heinz, TF, Experimental study of optical second-harmonic scattering from spherical nanoparticles, PHYSICAL REVIEW A (2006), 73 p. 023819. 25.502.12 Cattaneo, S, Kauranen, M, Bulk versus surface contributions in nonlinear optics of isotropic centrosymmetric media, PHYSICA STATUS SOLIDI B-BASIC SOLID STATE PHYSICS (2005), 242 p. 3007. 25.503.13 Cattaneo, S, Siltanen, M, Wang, FX, Kauranen, M, Suppression of nonlinear optical signals in finite interaction volumes of bulk materials, OPTICS EXPRESS (2005), 13 p. 9714. 25.504.14 Cattaneo, S, Kauranen, M, Polarization-based identification of bulk contributions in surface nonlinear optics (vol B 72, art no 033412, 2005), PHYSICAL REVIEW B (2005), 72 p. 169901. 25.505.1 ∗ 25.506.2 ∗ 25.507.3 ∗ Sun, L, Figliozzi, P, An, YQ, Downer, MC, Nonresonant quadrupolar second-harmonic generation in isotropic solids by use of two orthogonally polarized laser beams, OPTICS LETTERS (2005), 30 p. 2287. Mochan, WL, SHG from bulk and surface of nanoparticle composites, Physica Status Solidi C (2005), 2 p. 4062-4066. Wirth, A. and Wel, J. and Gielis, J. J. H. and Figliozzi, P. and Rafaelsen, J. and An, Y. Q. and Downer, M. C., Second-harmonic spectroscopy of Si nanocrystals embedded in silica, PHYSICA STATUS SOLIDI C (2008), 5 p. 2662-2666. 25.47 Del Artı́culo 7.2.60: Model for reflectance anisotropy spectra of molecular layered systems 25.508.1 Bussetti, G, Corradini, C, Goletti, C, Chiaradia, P, Russ, M, Paolesse, R, Di Natale, C, D’Amico, A, Valli, L, Optical anisotropy and gas sensing properties of ordered porphyrin films PHYSICA STATUS SOLIDI B-BASIC SOLID STATE PHYSICS (2005), 242 p. 2714. 25.48 Del Artı́culo 7.2.62: Nonresonant quadrupolar second harmonic generation in isotropic solids by use of two orthogonally polarized laser beams 25.509.1 Rodriguez, Francisco J. and Wang, Fu Xiang and Canfield, Brian K. and Cattaneo, Stefano and Kauranen, Martti, Multipolar tensor analysis of second-order nonlinear optical response of surface and bulk of glass, OPTICS EXPRESS (2007), 15 p. 8695-8701. 25.510.2 Cattaneo, S, Kauranen, M, Polarization-based identification of bulk contributions in surface nonlinear optics (vol B 72, art no 033412, 2005), PHYSICAL REVIEW B (2005), 72 p. 169901. 25.49 Del Artı́culo 7.2.64: Second harmonic spectroscopy of nano interfaces 25.511.1 ∗ Wirth, A. and Wel, J. and Gielis, J. J. H. and Figliozzi, P. and Rafaelsen, J. and An, Y. Q. and Downer, M. C., Second-harmonic spectroscopy of Si nanocrystals embedded in silica, PHYSICA STATUS SOLIDI C (2008), 5 p. 2662-2666. 65/74 25.50 Del Artı́culo 7.2.67: Second harmonic and reflectance anisotropy spectroscopy of vicinal Si(001)/SiO2 2 interfaces: Experiment and simplified microscopic model 25.512.1 Sano, H. and Miyaoka, M. and Iimori, T. and Sakiba, D. and Nakatsuji, K. and Wolf, W. and Podloucky, R. and Kawamura, N. and Mizutani, G. and Komori, F., Enhancement of optical second harmonic generation by nitrogen adsorption on Cu(001), APPLIED SURFACE SCIENCE (2008), 255 p. 3289-3293. 25.513.2 Gielis, J. J. H. and Gevers, P. M. and Aarts, I. M. P. and van de Sanden, M. C. M. and Kessels, W. M. M., Optical second-harmonic generation in thin film systems, JOURNAL OF VACUUM SCIENCE & TECHNOLOGY A (2008), 26 p. 1519-1537. 25.514.3 McGilp, J. F., Using steps at the Si-SiO2 interface to test simple bond models of the optical second-harmonic response, JOURNAL OF PHYSICSCONDENSED MATTER (2007), 19 p. 016006. 25.515.1 ∗ Ehlert, Robert and Kwon, Jinhee and Downer, Michael C., Optical second-harmonic and reflectance-anisotropy spectroscopy of molecular adsorption at Si(001) step-edges, PHYSICA STATUS SOLIDI C (2008), 5 p. 2551-2555. 25.51 Del Artı́culo 7.2.69: Full band structure LDA and k · p calculations of optical spin injection 25.516.1 ∗ Nastos, F. and Newson, R. W. and Hubner, J. and van Driel, H. M. and Sipe, J. E., Terahertz emission from ultrafast optical orientation of spins in semiconductors: Experiment and theory, PHYSICAL REVIEW B (2008), 77 p. 195202. 25.52 Del Artı́culo 7.4.1: Plasmons in Three, Two and One Dimension 25.517.1 Sharma, AC, Bajpai, A, Dynamical conductivity of low dimensional systems, International Journal of Modern Physics B, (2002), 16, p. 1511. 25.518.2 Yaneteka I, On the one-dimensional electron system with plasmon mediated interparticle interaction, Physica Status Solidi B, (1998), 206, p. 653. 25.519.3 Yaneteka I, Mean-field insight into the plasmon mechanism of the pairing arrangement in the one-dimensional electron-system, Physica Status Solidi B, (1996), 196, p. 379. 25.53 Del Artı́culo 7.6.1: Friction coefficients of human submandibular sublingual and parotid saliva 25.520.1 Smalley, JW, Dwarakanath, D, Rhodes, JM, Hart, CA, Mucin-sulfatase activity of some oral streptocicci, Caries Research, (1992), 28, p. 416. 25.521.2 Denny, PC, Denny, PA, Klauser, DK, Hong, SH, Navasezh M, Tabak, LA, Age-ralated-changes in mucins from human whole saliva, J. of Dental Research, (1991), 70, p. 1320. 25.522.1 ∗ Edgerton, M, Scannapieco, FA, Reddy, MS, Levine, MJ, Human submandibular-sublingual salive promotes adhesion of candida-albicans to polymethlymethacrylate, Infection and Inmunity, (1992), 61, p. 2644. 25.54 Del Artı́culo 7.6.2: Lubrication of selected salivary molecules and artificial salivas 25.523.1 Prakobphol, A, Xu, F, Hoang, VM, Larsson, T, Bergstrom, J, Johansson, I, Frangsmyr, L, Holmskov, U, Leffler, H, Nilsson, C, Boren, T, Wright, JR, Stromberg, N, Fisher, SJ, Salivary agglutinin, which binds Streptococcus mutans and Helicobacter pylori, is the lung scavenger receptor cysteine-rich protein gp-340, Journal of Biological Chemistry, 275, 39860 (2000). 25.524.2 Prakobphol, A, Tangemann, K, Rosen, SD, Hoover, CI, Leffler, H, Fisher, SJ, Separate oligosaccharide determinats mediate interactions of the low-molecular-weight salivary mucin with neutrophils and bacteria, Biochemestry 38, 6817 (1999). 25.525.3 Antonyraj, KJ, Karunakaran, T, Raj, PA, Bactericidal activity and poly-L-proline II confirmation of the tandem repeat sequence of human salivary mucin glycoprotein (MG2), Archives of Biochemestry and Biophysics 356, 197 (1998). 25.526.4 Vaderreijden, WA, Veerman, ECI, Amerongen, AVN, Rheological properties of commercially available polysaccharides with potential use in salive substitutes, Biorheology 31, 631 (1994). 25.527.5 Biesbrock, AR, Dirksen, T, Schuster, G, Effects of tun oil on salivary viscocity and extent and incidence of dental-caries in rats, Caries Research 26, 117 (1992). 25.528.6 GANS, RF, WATSON, GE, TABAK, LA, A NEW ASSESSMENT INVITRO OF HUMAN SALIVARY LUBRICATION USING A COMPLIANT SUBSTRATE, ARCHIVES OF ORAL BIOLOGY (1990), 35 p. 487. 25.529.1 ∗ 25.530.2 ∗ Reeh, ES, Douglas, WH, Levine, MJ, Lubrication of saliva substitutes at enamel-to-enamel contacts in an artificial mouth, J. of Prosthetic Dentistry 75, 649 (1996). 25.531.3 ∗ Reeh, ES, Douglas, WH, Levine, MJ, Lubrication of human and bovine enamel compared in an artificial mouth, Archives of Oral Biology 40, 1036 (1995). 25.532.4 ∗ 25.533.5 ∗ Ramasubbu, N, Reddy, MS, Bergey, EJ, Haraszthy, GG, Soni, SD, Levine, MJ, Large-scale purification and characterization of the major phosphoproteins and mucins of human submandibluar-sublingual saliva, Biochemical Journal 280, 341 (1991). 25.534.6 ∗ Khan, SH, Aguirre, A, Bobek, LA, In-situ hybridization localized MUC7 mucin gene expression to the mucous acinar cells of human and MUC7transgenic mouse salivary glands, Glycoconjugate Journal 15, 1125 (1998). Bobek, LA, Tsai, H, Biesbrock, AR, Levine, MJ, Molecular cloninf, sequence, and specificity of expression of the gene encoding the low-molecularweight human salivary mucin (MUC7), J.Biological Chem. 268, 20563 (1993). Douglas, WH, Reeh, ES, Ramasubbu, N, Raj, PA, Bhandary, KK, Levine, MJ, Statherin-a major boundary lubricant of juman saliva, Biochem. and Biophys. Res. Comm. 180, 91 (1991). 25.55 Del Artı́culo 7.6.3: In vitro characterization of human salivary lubrication 25.535.1 Hara, Anderson T. and Gonzalez-Cabezas, Carlos and Creeth, Jonathan and Zero, Domenick T., The effect of human saliva substitutes in an erosion-abrasion cycling model EUROPEAN JOURNAL OF ORAL SCIENCES (2008), 116 p. 552-556. 66/74 25.536.2 Schipper, Raymond G. and Silletti, Erika and Vinyerhoeds, Monique H., Saliva as research material: Biochemical, physicochemlical and practical aspects ARCHIVES OF ORAL BIOLOGY (2007), 52 p. 1114-1135. 25.537.3 Zussman, E. and Yarin, A. L. and Nagler, R. M., Age- and flow-dependency of salivary viscoelasticity JOURNAL OF DENTAL RESEARCH (2007), 86 p. 281-285. 25.538.4 Prinz, J. F. and de Wijk, R. A. and Huntjens, L., Load dependency of the coefficient of friction of oral mucosa FOOD HYDROCOLLOIDS (2007) 21 p. 402-408. 25.539.5 Ang, KY, Lucas, PW, Tan, HTW, Incisal orientation and biting efficiency JOURNAL OF HUMAN EVOLUTION (2006), 50 p. 663. 25.540.6 Ranc, H, Elkhyat, A, Servais, C, Mac-Mary, S, Launay, B, Humbert, P, Friction coefficient and wettability of oral mucosal tissue: Changes induced by a salivary layer, COLLOIDS AND SURFACES A-PHYSICOCHEMICAL AND ENGINEERING ASPECTS (2006), 276 p. 155. 25.541.7 Berg, CH, Lindh, L, Arnebrant, T, Intraoral lubrication of PRP-1, statherin and mucin as studied by AFM BIOFOULING (2004), 20 p. 65. 25.542.8 Berg, ICH, Rutland, MW, Arnebrant, T, Lubricating properties of the initial salivary pellicle - an AFM Study BIOFOULING (2003), 19 p. 365. 25.543.9 Turssi, CP, Purquerio, BDM, Serra, MC, Wear of dental resin composites: Insights into underlying processes and assessment methods - A review, JOURNAL OF BIOMEDICAL MATERIALS RESEARCH PART B-APPLIED BIOMATERIALS (2003), 65B p. 280. 25.544.10 Katona, TR, A mathematical analysis of the role of friction in occlusal trauma JOURNAL OF PROSTHETIC DENTISTRY (2001), 86 p. 636. 25.545.11 Rantonen, PJF, Meurman, JH, Viscosity of whole saliva ACTA ODONTOLOGICA SCANDINAVICA (1998), 56 p. 210. 25.546.12 Prakobphol, A, Thomsson, KA, Hansson, GC, Rosen, SD, Singer, MS, Phillips, NJ, Medzihradszky, KF, Burlingame, AL, Leffler, H, Fisher, SJ, Human low-molecular-weight salivary mucin expresses the sialyl Lewis(x) determinant and has L-selectin ligand activity, BIOCHEMISTRY (1998), 37 p. 4916. 25.547.13 LUCAS, PW, PETERS, CR, ARRANDALE, SR, SEED-BREAKING FORCES EXERTED BY ORANGUTANS WITH THEIR TEETH IN CAPTIVITY AND A NEW TECHNIQUE FOR ESTIMATING FORCES PRODUCED IN THE WILD, AMERICAN JOURNAL OF PHYSICAL ANTHROPOLOGY (1994), 94 p. 365. 25.548.14 NEDERFORS, T, HENRICSSON, V, DAHLOF, C, AXELL, T, ORAL MUCOSAL FRICTION AND SUBJECTIVE PERCEPTION OF DRY MOUTH IN RELATION TO SALIVARY SECRETION, SCANDINAVIAN JOURNAL OF DENTAL RESEARCH (1993), 101 p. 44. 25.549.15 JENSEN, JL, LAMKIN, MS, OPPENHEIM, FG, ADSORPTION OF HUMAN SALIVARY PROTEINS TO HYDROXYAPATITE - A COMPARISON BETWEEN WHOLE SALIVA AND GLANDULAR SALIVARY SECRETIONS, JOURNAL OF DENTAL RESEARCH (1992), 71 p. 1569. 25.550.16 JAY, GD, HONG, BS, CHARACTERIZATION OF A BOVINE SYNOVIAL-FLUID LUBRICATING FACTOR .2. COMPARISON WITH PURIFIED OCULAR AND SALIVARY MUCIN, CONNECTIVE TISSUE RESEARCH (1992), 28 p. 89. 25.551.17 GANS, RF, WATSON, GE, TABAK, LA, A NEW ASSESSMENT INVITRO OF HUMAN SALIVARY LUBRICATION USING A COMPLIANT SUBSTRATE, ARCHIVES OF ORAL BIOLOGY (1990), 35 p. 487. 25.552.1 ∗ Reeh, ES, Douglas, WH, Levine, MJ, Lubrication of saliva substitutes at enamel-to-enamel contacts in an artificial mouth, PROSTHETIC DENTISTRY (1996), 75 p. 649. 25.553.2 ∗ 25.554.3 ∗ JOURNAL OF REEH, ES, DOUGLAS, WH, LEVINE, MJ, LUBRICATION OF HUMAN AND BOVINE ENAMEL COMPARED IN AN ARTIFICIAL MOUTH ARCHIVES OF ORAL BIOLOGY (1995), 40 p. 1063. RAMASUBBU, N, REDDY, MS, BERGEY, EJ, HARASZTHY, GG, SONI, SD, LEVINE, MJ, LARGE-SCALE PURIFICATION AND CHARACTERIZATION OF THE MAJOR PHOSPHOPROTEINS AND MUCINS OF HUMAN SUBMANDIBULAR-SUBLINGUAL SALIVA, BIOCHEMICAL JOURNAL (1991), 280 p. 341. 25.56 Del abstract 23.6: Longitudinal plasmon modes in a two dimensional array of quasi one dimensional wires 25.555.1 26 ∗ Schaich W, Calculations of second-harmonic generation for a jellium metal surface, Phys. Rev. B 61, 10478 (2000). Distinciones 26.1 Investigador Nacional Nivel III (S.N.I.) en el area de Ciencias Básicas (12084). 26.2 Miembro de la Academia Mexicana de Ciencias. 26.3 Beca de la Deutscher Akademischer Austauschdienst (DAAD, Alemania), para realizar una estancia de investigación por dos meses en Berlin. Programa ANUIESDAAD. 26.4 Beca de la Academia Mexicana de Ciencias y la Fundación México-Estados Unidos para la Ciencia, dentro del programa Estancias de Verano en E.U. para Investigadores Jóvenes. 26.5 Beca de Año Sabático otorgada por el Consejo Nacional de Ciencia y Tecnologı́a. Septiembre 1997 a Agosto 1998. 67/74 26.6 Beca de Repatriación otorgada por el Consejo Nacional de Ciencia y Tecnologı́a. Agosto 1991 a Agosto 1992. 26.7 Estancia Posdoctoral en el grupo de Materia Condensada del Departamento de Fı́sica de la U. de Indiana en Bloomington, de Septiembre de 1989 a Agosto de 1991. 26.8 Beca Doctoral otorgada por Consejo Nacional de Ciencia y Tecnologı́a y por la State University of New York at Buffalo de Septiembre 1984 a Agosto 1989. 27 Apoyo a Proyectos de Investigación 27.1 Apoyo para alumnos de Licenciatura del S.N.I. Sistema Nacional de Investigadores, por $43,500, de enero del 2009 a junio del 2010. 27.2 Glucómetro Óptico no invasivo. Consejo de Ciencia y Tecnologı́a del Estado de Guanajuato, por $200,000, de Marzo del 2008 a Febreo del 2009. 27.3 Photon assisted spintronics. Consejo Nacional de Ciencia y Tecnologı́a, por $1,300,000, de Marzo del 2007 a Febreo del 2010, 48915-F. 27.4 Second Harmonic Spectroscopy from Interfaces. Consejo Nacional de Ciencia y Tecnologı́a. Grant 36033 por $1,500,000. 2002-2005. Finalizado. 27.5 Reflectance anisotropy spectroscopy from Si(110) surfaces. estancia de investigación con el Dr. Norbert Esser y Prof. Wolfgang Richter de la U. Técnica de Berlin. Programa ANUIES-DAAD 2001-2002. 27.6 Propiedades Opticas Lineales y No-Lineales de Interfaces Metálicas y Semiconductoras, Consejo Nacional de Ciencia y Tecnologı́a, por $ 800,000. Enero de 1998 a Diciembre de 2001. Proyecto Num. 26651-E. Obtuvo el 4o lugar. 27.7 Generación del Segundo Armónico en Superficies de Si (100) dopadas con Boro, Estancia de Verano en EE.UU. para Investigadores Jovenes, Academia Mexicana de Ciencias y Fundación México-estados Unidos para la Ciencia. Verano de 1999 en la U. de Texas en Austin, con el Profesor Michael Downer del Departamento de Fı́sica. 27.8 Second harmonic generation at semiconductor surfaces Consejo Nacional de Ciencia y Tecnologı́a,-Consiglio Nazionale delle Ricerche 68/74 (CNR-Italy). Con el Profesor Rodolfo del Sole (U. de Roma II) Proyecto Num. E130.1472. Trienio 96-98. 27.9 Generación del Segundo Armónico en medios inhomogeneos, Consejo Nacional de Ciencia y Tecnologı́a, Por 96,900 nuevos pesos. Proyecto Num. 3246-E9308. Septiembre de 1994 a Abril de 1997. Evaluación final: Excelente. 27.10 Generación del Segundo Armónico en Superficies Cristalinas, Consejo Nacional de Ciencia y Tecnologı́a, por 192,900 nuevos pesos. Enero de 1992 a Abril de 1994. Proyecto Num. 0642-E9109. Evaluación final: Bueno. 28 Formación de Grupos 28.1 Intrainstitucionales-CIO Grupo de Propiedades Opticas de Superficies: 28.1.1 Dr. Norberto Arzate Plata, Investigador Titular A, S.N.I. nivel I 22296, doctorado bajo mi supervición, postdoctorado con el profesor John Sipe en la U. de Toronto, Canadá. Alumnos A. Carlos Miguel González Juárez, Licenciatura, U. de Guadaljara, Graduado 2006. Estudio de la estructura electrónica de sistemas con simetrı́a exagonal. B. Noé González Baquedano, Maestrı́a, CIO. 4to semestre. Proyectos Apoyados o Solicitados A. Pruebas fotónicas para el estudio de superficies de semiconductores Consejo Nacional de Ciencia y Tecnologı́a, CONACYT, SEP-2003-C0242576, 500,000.00 MX, 2004-2007. B. Propiedades Ópticas en Superficies de Semiconductores: Inyección Óptica de corrientes y Procesos No Lineales Consejo de Ciencia y Tecnologı́a del Estado de Guanajuato, CONCYTEG 03-04-k118-039, 04-04-k117-011-A02, 05-04-k117-026-A03, 200,000 MX, 2003-2006. 28.1.2 Dr. Raúl Vázquez Nava, Investigador Asociado C, S.N.I. nivel I 19594. Alumnos A. Enrique Aragón Navarro, Maestrı́a, U. de Guadalajara. 3er semestre. Proyectos Apoyados o Solicitados 69/74 28.1.3 28.1.4 28.1.5 28.1.6 28.1.7 A. Estudio Teorico de propiedades opticas de estructuras cristalinas con simetria FCC. Consejo de Ciencia y Tecnologı́a del Estado de Guanajuato, CONCYTEG.03-04-k118-39 anexo 5 y 04-04-k117-011 anexo 4, 20032005. Finalizado. B. Reflectancia Anisotropica de Pelı́culas Orgánicas y Superficies Semiconductoras, SEP-2004C01-48142 (CONACYT), 2004-2007. Dr. Enrique Castro Camus-Recien Contratado, Investigador Titular A. Doctorado y Posdoctorado en Oxford, Reino Unido. Proyectos Apoyados o Solicitados A. Estudio de dinámica vibracional de biomoléculas en el infrarrojo lejano. Conacyt, en evaluación. Dr. Ramón Carriles Jaimes-Recien Contratado, Investigador Titular A, S.N.I. candidato 42371. Doctorado en la U. de Texas en Austin y Posdoctorado en la Escuela de Minas de Colorado, EEUUA. Proyectos Apoyados o Solicitados A. Espectroscopia de segundo armónico óptico para caracterización de superficies e interfases. Conacyt, en evaluación. Dr. Jorge E. Mejı́a Sánchez, Investigador Asociado C, S.N.I. Nivel I 26430. doctorado bajo mi supervición, postdoctorado con el profesor Theo Rasing en la U. de Nijmegen, Holanda. Actualmente, el Dr. Mejı́a trabaja en la U. de Guadalajara. Proyectos Apoyados o Solicitados A. Espectroscopı́a óptica de estructuras ordenadas y parcialmente ordenadas Consejo de Ciencia y Tecnologı́a del Estado de Guanajuato, Concyteg 04-04-K117-011 A1, 99,000 MX, 2004-2005. Finalizado. B. Espectroscopı́a óptica de estructuras ordenadas y parcialmente ordenadas. Apoyado por el Consejo de Ciencia y Tecnologı́a del Estado de Guanajuato, convenio núm. 05-04-K117-026 Anexo 04. Duración: 01/06/05 - 31/05/06. C. Técnicas fotónicas aplicadas a estructuras ordenadas y parcialmente ordenadas. Consejo Nacional de Ciencia y Tecnologı́a, CONACYT, 600,000.00 MX, 2006-2009. Dr. Cesár Castillo Quevedo, S.N.I. candidato 35656. Departamento Transdiciplinar, Universidad de Guadalajara, Campus Lagos de Moreno, Jalisco. doctorado bajo mi supervición, y realizará el postdoctorado en el CIO bajo mi supervición. M. en C. José Luis Cabellos Quiroz, Tesista de Doctorado Asistente de Investigación. 70/74 28.1.8 M. en C. Luis Adán Martı́nez Jiménez, Tesista de Doctorado. 28.1.9 M. en C. Juan Cuauhtemoc Salazar González, Tesista de Doctorado. 28.1.10 Ernesto Carlos Cortés Morales, Tesista de Licenciatura, IFUG. 28.2 Interinstitucionales 28.2.1 28.2.2 28.2.3 28.2.4 28.2.5 28.2.6 28.2.7 28.2.8 28.2.9 28.2.10 Dr. Wolf Luis Mochán Backal, ICF-Cuernavaca, UNAM, México. Dr. Jesús Maytorena, CMC-Ensenada, UNAM, México. Dr. Eugenio Mendéz Méndez, CICESE-Ensenada, México. Dr. Rodolfo Del Sole, U. de Roma II, Italia Dr. Michael Downer, U. de Texas en Austin, EE.UU. Dr. Wolfgang Richter, U. Tecnica de Berlin, Alemania. Dr. Norbert Esser, BESSY, Berlin, Alemania. Dr. John Sipe, U. de Toronto, Canada. Dra. Vera Brudny, U. de Buenos Aires, Argentina. Dr. Guillermo Ortiz, U. del Nordeste, Argentina. 71/74 29 Totales 29.1 Total de Artı́culos: 113 (suma de •) (ver 7 en la página 13). • Artı́culos sin Arbitraje: 10 – de investigación: 2 – de divulgación: 8 • Artı́culos con Arbitraje: 89 – en revistas: 73 ∗ publicados: 70 ∗ interdiciplinarios publicados: 3 ∗ aceptados: 0 – en libros: 1 – de docencia: 1 – en memorias in extenso: 14 • Capı́tulos en Libros: 3 • Artı́culos enviados: 1 • Artı́culos en preparación: 10 29.2 Total de Alumnos: 15 (suma de •) (ver 16 en la página 27). • • • • Doctorado: 4 Maestrı́a: 6 Licenciatura: 1 En Proceso: 4 29.3 Total de Proyectos: 10 (ver 27 en la página 68). 29.4 Presentaciones en Congresos: 169 (suma de •) (ver 22 en la página 32 y 23 en la página 38 ). • Nacionales: 58 • Internacionales: 111 29.5 Citas: 555 Actualizadas al 12 de enero del 2008. (ver 25 en la página 49) 72/74 30 Referencias 30.1 Dr. Rubén Barrera Instituto de Fı́sica Universidad Nacional Autónoma de México México, D.F. [email protected] 30.2 Dr. Yung C. Lee Department of Physics State University of New York Bauffalo Amherst, New York 14260, U.S.A. [email protected] 30.3 Dr. William L. Schaich Department of Physics Indiana University Bloomington, Indiana [email protected] 30.4 Dr. Michael Downer Department of Physics University of Texas Austin, Texas [email protected] 30.5 Dr. Wolfgang Richter Department of Physics Berlin Technical University Berlin, Germany [email protected] 30.6 Dr. Rodolfo Del Sole Dipatimento di Fisica Universita di Roma II Tor Vergata, Roma [email protected] 30.7 Dr. John Sipe Department of Physics University of Toronto Toronto Canadá [email protected] 73/74 31 Intereses Personales Música Clásica, Jazz, Lectura, Ciclismo de Montaña, Triatlones, Carrera de Resistencia, jugar Tenis, Acampar y Viajar. Actualizado al 3 de febrero de 2009 Dr. Bernardo Mendoza Santoyo [email protected] 74/74