B - Instituto de Física / UFRJ
Transcription
B - Instituto de Física / UFRJ
Física 3 - 2013/1 Instituto de Física - UFRJ Campo magnético e força magnética Prof. João T. de Mello Neto Referências • • 1. 2. 3. 4. 5. Atenção: esta apresentação é apenas para uso interno do curso de Física 3 - UFRJ 2013/1. Referências: Física 3, 12a. edição, Young e Freedman, Pearson Education do Brasil. (Quase todas as figuras foram retiradas desta referência) H. M. Nussenzveig, "Curso de Física Básica 3: Eletromagnetismo." Edgard Blücher, São Paulo, Brasil, 1997. P. A. Tipler & G. A. Mosca, "Física para Cientistas e Engenheiros 2: Electricidade, Magnetismo e Óptica, 6a. ed." LTC, Rio de Janeiro, 2009. Fundamentos da Física, vol. 3 (Eletromagnetismo), Quarta Edição, Halliday, Resnick, Walker, Livros Técnicos e Científicos Editora S.A. Outras citadas na apresentação. MAGNETIC FORCES Introdução Imageamento por ressonância nuclear permite o exame dos tecidos moles do pé que não são visíveis por raios X. No entanto os tecidos moles não são magnéticos. Como a técnica de RMN funciona? Força magnética: motores elétricos, circuitos de TV, fornos de microondas, alto-falantes... Mais familiares: mã permanente, agulha de uma bússola. Natureza fundamental do magnetismo: interação produzida por cargas elétricas que se movem. As forças magnéticas só agem em cargas em movimento. Um conjunto de cargas em movimento PRODUZ um campo magnético. A seguir, uma segunda corrente ou cargas em movimento reage a esse campo magnético e sofre a ação de uma força magnética. Neste capítulo: campo magnético DADO, como ele age em cargas e correntes?? next to each other. (b) The bar magnets repel when like poles (N and N, or S and S) Interação entre magnetos are next to each other. (a) Opposite polesseattract. Polos opostos atraem S N N S F F F F S N N S (b) Likeiguais poles repel. Polos se repelem F F S N N S N S S N F F an iron rod magnetized. its center, it ordinary com Before th stood, the in in terms of m free to rotate other end is poles repel magnetized either pole between a m to electric in ing that a ba body respon which varies with locatio ins iron, such as a nail. (b) A real-life Materiais não magnetizados xample of this effect. (b) Also, the magnetic field t d ) b) S N N S F F F F angle up or down is call netic field is vertical. Figure 27.3 is a sketc field lines, show the dire are discussed in detail in be defined as the directi 27.3 A sketch of the eart the earth’s molten core, cha direction entirely at irregul North geographic pole (earth’s rotation axis) O campo magnético da Terra 27.3 A sketch of the earth’s magnetic field. The field, which is caused by currents in the earth’s molten core, changes with time; geologic evidence shows that it reverses direction entirely at irregular intervals of 10 4 to 10 6 years. Polo norte North geographic pole geográfico (earth’s rotation axis) The geomagnetic north pole is actually Polo norte geomagnético é a magnetic south (S) pole—it attracts um sul magnético the Npolo pole of(S) a compass. Compass bússola Magnetic field lines show the direction a compass would point at a given location. S The earth’s magnetic field has a shape similar to that produced by a simple bar magnet (although actually it is caused by electric currents in the core). N The earth’s magnetic axis is offset from its geographic axis. Polo polo The geomagnetic sul geomagnético é um south pole is actually a north (N) pole. magnetic (N) norte magnético South geographic Polo sul pole geográfico magnéticos X cargas elétricas ieces arePólos different sizes. (The smaller the iece, the weaker its magnetism.) • Não existe nenhuma evidência experimental de pólos magnéticos isolados (monopolos). partida ao meio: dois outros imãs completos! • Barra imantada In contrast to electric charges, magnetic poles • Existência de monopolos magnéticos é um tema quente na física: importantes para acan't cosmologia, física de partículas, always comeconsequências in pairs and be isolated. etc. Breaking a magnet in two ... N N S S N S (here viewed from above). When the comExperimento de Oersted is placedconnected. directly under opass be intimately Overthe thewire, the compass deflection is reversed. nifying principles of electromagnet- S (1819) points north. I50 (b) principles in Maxwell’s equations. (a) When the wire carries a current, the compass electromagnetism, just as Newton’s needle deflects. The direction of deflection cs, and like Newton’s laws they repdepends on the direction of the current. N When the wire intellect. I carries no W E current, the .1 Suppose you cut off the part of the N compass needle d gray. You discard this part, drill a hole points north. S n the pivot at the center of the compass. current is applied as in Fig. 27.5b? ❙ W I50 I N E W S I I (b) When the wire carries a current, the compass needlelet’s deflects. Theour direction of deflection roperly, review formulation Forças magnéticas : produzidas fundamentalmente pelo efeito magnético depends on the direction of the current. we introduced the concept of electric dos elétrons dos átomos no interior dos corpos. two steps: E S where q ƒ is theismagnitude of the charge andBfare is ƒ that component zero (that is, when and v S agnetic S v F = q vB !Bq, vas B direction of v to the direction of shown in the force is zero. rce. F = = q vB si ƒ ƒ ƒ ƒ ! S This formB is sometimes more convenient, This description does not specify theThe directio Figure 27.6 shows these relationships. direc q S S arge moving parallel tov a magnetic field S This form is sometimes more convenient, especially + always two opposite toBcharge each other, that cular to the plane vofand . Its magnitude where isdirections, theScontaining magnitude the and fw i harge moving f to a magnetic ƒ qSƒ individual riences zero at an angle currents rather than particles. We S S q S plane of v and Todirection complete d experiences a magnetic force with netic currents rather direction ofparticles. v toB.the ofthe B, description, as discuss shown in we th v than individual We will 0 vB sin f. 5 0 q this e. Fnot= specify chapter. thatThis we used to definedoes the vector inƒ qSection ƒ qproduct ƒ v! B =the ƒ vB sin )gnitude F 5 0 q 0 v!B in S description directio B in this chapter. SS q to reviewtwo thatdirections, section before you go on.) Draw the always opposite to each other, tha v charge moving at an angle f to a magnetic F + From Eq. (27.1) the units of B must be the S S S the where q is magnitude of the charge and f is s perpendicƒ ƒ together, as in Fig. 27.7a. Imagine turning v until plane of of v Sand B . To complete description, w Sthe From Eq. (27.1) the units B must be the same as th ld experiences a magnetic force Swith r to the plane direction of vis to the of the Bproduct ,to as shown in s>C the (turning through thedirection smaller of two possible an B f. SI unit 5 0 q 0 vB the sin gnitude F 5 0 q 0 vq!Bfore of B equivalent 1 N that we used to define the vector in Section S taining equivalent to 1 N s>C m, or, si S fore the SI unit of B is This description does not specify the direction right hand around the line perpendicular to the pla B S f to review that section before you go on.) Draw the nd B. S S S v! coulomb per second 11 A = 1 C>s2, 1 N>A F S v always two directions, opposite to each other, that v B . around with the sense of rotation from to Your arge moving at an angleper f to a magnetic s perpendiccoulomb second 11 A = 1 C>s2, 1 N>A m. This u together, as in Fig. 27.7a. Imagine turning v unti S S S S plane of v and B . To complete the description, we rexperiences to the planea magnetic force with F tion of the force on a positive charge. (Alternati (turning through theof smaller of the two possible ant B (abbreviated T), in honor Nikola Tesla (18 S q (abbreviated T), in honor of Nikola Tesla (1856–1943), 0 0 0 0 nitude F 5 q v!B 5 q vB sin f. S ntaining that we used to define the vector product in Section 1 F on a positive charge is the direction in which a r S right hand around the line perpendicular to the pla B fS nd B. S the v SDraw v American scientist and inventor: S to review that section before you go on.) ! advance if turned the same way.) v American scientist and around inventor: with the sense of rotation from v toSB. Your F S harge moving perpendicular to a magnetic together, perpendicas in Fig.F27.7a. Imagine turning v until i This discussion shows that the force on a charge tion of the force on a positive charge. (Alternat S S d experiences force to the plane a maximal magnetic S (turning through the smaller of direction the two possible ang B B magnetic field is given, both in magnitude and q 1 tesla = 1 T = 1 F on a positive charge is the in which ain 1 tesla = T = 1 N>A m h magnitude S aining S right hand ifaround the line perpendicular toSthe plan B fS 5 qvB. v S dax B. advance turned the same way.) S Fmax ! v S S v toon Ba. Your with the S sense of rotation from t charge moving perpendicular to a magnetic around -4 -4 This discussion shows that the force charg S F ! qv : B (magnetic force on a mo 11 G = 10 Another unit of B, the gauss T2, is also in co S 11 G = 10 Another unit of B, the gauss T2, ld experiences a maximal magnetic force F tion of the force on a positive charge. (Alternativ S S magnetic field B is given, both in magnitude and i B q + th magnitude Fof on athe positive charge isof thethe direction in which a ri 10 The magnetic field earth is order of S The magnetic field of the earth is of the o ax 5 qvB. This is the first of several vector products we w S advance ifSturnedS the same way.) S vFmax fields offields the order of 10 T occur in the of atoms arge moving perpendicular to aof magnetic magnetic-field relationships. It’sforce important n F! qv : B interior (magnetic force on to a ma This discussion shows that the on a charge the order of 10 T occur in the interior S S experiences a maximal magnetic force deduced theoretically; it is an observation on B magnetic field B is given, both in magnitudebased and in q q S Campo magnético ƒ ƒ # # # # # Produto vetorial n of the magnetic force on a moving charged particle. (b) ction of magnetic force on a positive charge moving in a magnetic field: S S 1 S S d B in the v-B r angle). e perpenCurl the around tion you w points acts. S S F 5 qv 3 B tail to tail. S If the charge is n of the force is op the right-hand ru B q S v plano 3 q 2 S v Force acts along this line. S S v-B plane S v 1 F5 2 1 S q 3 S B S S Right Mão hand! direita S v q S F 5 qv 3 B d for both positive and negative charges. When q is neg- 27.8 Two charges of S velocity in the same magnetic field. The If the charge is negative, the direction in the same B field with Produto vetorial magnetic forces on the charges are equal in of the force is opposite to that given by magnitude and opposite magnitude but opposite in direction. the right-hand rule. mples of the relationships negative charges. Be sure S 1 B . S q Eq. (27.2). We force F in S 2 way. Since fvis the angle S S S erpret B sin fF as the3com5 qv B S magniS S notation the force F 5 qv 3 B Positive and negative charges moving in the same direction through a magnetic field experience magnetic forces in opposite S S S directions. F 5 qv 3 B S S v q B y in problems involving ss forces on currents later the units of F>qv. There- f S (27.3) S B q1 5 q . 0 q2 5 2q , 0 S v S S v B f S S F 5 (2q)v 3 B rce F is the vector sum of the electric and magnetic forces: S S S S Medida do campo magnético F ! q1E " v : B2com cargas teste(27.4 y ) If the tube axis parallel to the xis, the beamSis deflected, so B is either the 1y- or 2y-direction. (b) If the tube axis is parallel to the x-axis,Sthe beam is deflected in the 2z-direction, so B is the 1y-direction. y S B S v S S F B x S v z feixe de elétrons Electron beam z x field line is tangent the field lines are Linhas de campo magético e fluxo to the magnetic packed, the stronger S field vector B. the field is at that point. S B Linhas do campo magnético não são linhas de força S B S At each point, the N . . . therefore, magnetic gnetic field lines produced by some common sources of magnetic field. Linhas de campo(b)magnético Magnetic field of a straight current-carrying wire (a) Magnetic field of a C-shaped magnet Between flat, parallel magnetic poles, the magnetic field is nearly uniform. S To represent a field coming out of or going into the plane of the paper, we use dots and crosses, respectively. B S B directed out of plane I S B I I I S B directed into plane S B Perspective view Wire in plane of paper (c) Magnetic fields of a current-carrying loop and a current-carrying coil (solenoid) I I S B I I Notice that the field of the loop and, especially, that of the coil look like the field of a bar magnet (see Fig. 27.11). S B S Linhas de campo magnético B (b) (a) S B limalha de ferro Linhas de campos magnéticos não tem um "fim" ences to help it navigate. Física e vida: lagosta do caribe ences to help it navigate. Física e vida: lagosta do caribe Embora tenha um sistema nervoso relativamente simples, ela é incrivelmente sensível a campos magnéticos. Ela tem uma bússola magnética interna que a permite distinguir sul, norte, leste e oeste. Ela também sente pequenas diferenças no campo magnético da Terra que podem ajudá-la a se orientar. The total magnetic flux through the surface isFor the sum of theoncontribu this component varies from point to point surf total electric charge enclosed by the surface. example, ifthethe £ B = B! A = BA cos f Fluxo magnético individual area elements: 27.15 Thethe magnetic through anflux area this flux component varies from to this point onasthe surface. We define d£ B point through area Selectric dipole, the total electric flux is zero becaus ncloses an lement dA is to d£ be Bto d£ Bthis flux through area as to the surface, then cos f = B =perpendicular ! dA. B happens If defined be d£ B = B! dA = B cos f dA = e is zero.reduces (You may want to review Section Gauss’s law flux S22.3 S on(magnetic S S = BA. We will use the concept of magnetic flux # # ic Field and Magnetic d£ = B dA = B cos f dA = B dA £ B =to £BBForces dA = B cos f dA = B dA B ! ! The total magnetic flux through the surfaceaissurfac the sum through f there were such a thing as a single magnetic charge (magnetic L of electromagnetic L L S ing our study induction in Chapter 29. the individual area elements: B The total magnetic flux through the surface is the sum of the contri f B tal magneticThe flux a closed surface would be proportional 'through SI unit of magnetic flux is equal to the unit of magnetic fie theFor individual areaconcepts elements: (This equation uses of vector area and surface integral th 2 the Gauss’s law, which always deals with closed 11Sm ). This unit of in area unit called the (1 hon # etic charge enclosed. But we mentioned that noWb), £ B is =want B!todAreview = weber Bthat cos fdiscussion.) dA = magnetic Bin dA SSection duced 22.2; youhave may S points L L S Sout (magnetic L dA Wilhelm ment dA in Eq. (27.6) always of the surfa fluxs physicist Weber (1804–1891): ver been observed, despite intensive searches. We conclude: Magnetic flux is a scalar quantity. If B is uniform over a plane £B = B! dA = B cos f dA = B # dA through a surfa tions of magnetic flux involve an open surface with (This equation uses the concepts of vector area and su L the same at all Lpoints on total area A, BthenL B! and f are the surface, a 2 # 1 Wb = 1 T m duced in Section 22.2; you may want to review thattw d campo an ambiguity of sign in Eq. (27.6) because of the dA S uses (Thisthrough equation theMagnetic concepts area and surface t is=is a BA scalar If B integral is uniform total magnetic flux a closed always £ = Bflux cosquantity. f zero. uniforme B surface !ofAvector # tion for dA . In these cases we choose one of the two 1 T = 1 N>A m, Also, so total area A, then B and f are the same at all points duced in Section 22.2; you may want to review that discussion.) na superfície ! S S f =a 1plane If B happens to beside perpendicular to thechoice surface, then cosover and Magnetic flux isand a scalar If B isconsistently. uniform “positive” use quantity. that A = BA cos f 2 £ B = B! # # 1 Wb = T m 1 N =A,BA. reducestotal to £area of=points magnetic flux exten mbolically, thenWe B! will and fuse arethe the1concept same at all onm>A the surface, B If the elementIf Bofhappens area dA in Eq. (27.5) is at right to be perpendicular ing our study of electromagnetic induction in Chapter to 29.the surface, the ££BBdA ==flux BBA. = will BA cos B! = B; calling the area ,Awe !the reduces toequal We concept of(1 maT In Gauss’s law the total through afthe closed surfac The SI unit of magnetic fluxelectric is to! unithave ofuse magnetic field S S i S S # ing enclosed our study ofby electromagnetic induction in Chapter 2 charge total electric the surface. For example, 11 m ). This unit of If area unit is called the weber (1 Wb), in honor ofant Lei de Gauss para B cos f = 1 happens to be perpendicular to the surface, then (magnetic surface B dA = 0 Theflux SI unitthrough of magnetic any flux isclosed equal to the unit of m d£ B o =magnetismo physicist Wilhelm Weber (1804–1891): £ BA. reduces to We will use concept of magnetic flux exte 2the face encloses an electric dipole, the total electric flux is zero B B = 11 m ). unit of area This unit is called the weber (1 W C ingzero. our study of may electromagnetic induction in Chapter 29.! dA physicist Wilhelm Weber (1804–1891): charge is (You want to review Section 22.3 on Gauss 2 # hET: Magnet and Compass S to the S S 1 Wb = 1toTthemunit of magnetic field (1 The SI unit of magnetic flux is equal R The particle therefore moves under the influence of a constant-m F = where is the mass the particle. Solving Eq. (27.10) for (a) The orbit ofm a charged particle in aof uniform that is always atpartículas right angles toem the velocity of the particle. Compar Movimento de campos magnéticos magnetic field circular we find sion path, of circular motion in Sections 3.4 and 5.4, we see that the par S here is the mass of the particle. Solving Eq. A charge m moving at right angles to a uniform B circle, traced out with constant speed v. The centripetal accelerati field moves insob a circle constant speed Movimento açãoatde forças magnéticas apenas se dámass sempre com velocidade where m is the of the particle S only the magnetic force acts, so from Newton’s second law, S mv rcular path, weperpendicular find because F and v are always to constante each other. R = S v (radius ofwe a circular orbit in a magn circular path, find ƒqƒB v2 mv S F = ƒ q ƒ vB = m R mv R = p> p = mvorbit We canRalso write this as q B, where is th ƒ ƒ = (radius of a circular S where m isFthe mass of the particle. for the r R = Solving Eq. (27.10) (radius of raiosthe parapartic uma q particle’s momentum. If the charge is negative, q B ƒ ƒ circular path, we find ƒqƒB R órbita circular around the orbit in Fig. 27.17a. The angularS speed mvS v of the particle can be found from E RF = (radius of a circular orbit in a magnetic fi v Combining this with (27.11), get R = p> We can R we =write p> ƒ qthis pƒ can alsoS write asalso ƒ B, aswhere ƒ q this ƒ BEq. We P F particle’s momentum. Ifisthe charge q article’s momentum. If the charge negative q B q B ƒ ƒ ƒ ƒ v R = p> p = mv We can also write this as q B, where is the ma ƒ ƒ v around the orbit in Fig. 27.17a. v = = = v O round the orbit in Fig.If27.17a. B particle’s momentum. the charge themparticle m mv R q is negative, The27.17a. angular speed v of the part around the orbit in Fig. v The angular speed of the particle can be fo The angular speed v of the particle can be found from Eq. (9 S S Combining thistime withis Eq. we ƒ = (27.11), v>2p. This per unit The number of asrevolutions (b) An electron beam (seen a white arc) parallel (vi) and perpendicular (v') to the caso geral magnetic Movimento field, so it moves in a helical path. y v' S v vi z q S B x Visualzação de um feixe de elétrons Garrafas magnéticas and Magnetic Forces ear agion. ed of rial elts ed alis f S S v B S v S B + S F I S F I S F Coil 1 1 Bobina S B S v (b) (a) Charged particles from sun enter earth’s magnetic field Protons trapped in inner radiation belts Coil 22 Bobina F Coil 1 S Coil 2 B S v (b) (a) partículas carregadas Charged particles sun enternoearth’s dofrom sol entram magnetic campo mag.field da Terra prótons presos nos Protons trapped cinturões de radiação in inner radiation internos belts North Pólo Pole Norte Pólo South Sul Pole Magnetic forces on charged particles play an important role in studies of elementary particles. Figure 27.21 shows a chamber filled with liquid hydrogen and area A using the on the wire segment is then length l of conductor with cross-sectional area A using t ing charges are positive. Later we itive. Later we’ll see what happens when they are ne magnética sobre um condutor com corrente nt has magnitude S edForça in Eqs. (25.2) and (25.3) of Section 25.1. The S number l along the wire in th S used in Eqs. (25.2) and (25.3) of Section 25.1. The numb The drift velocity is upwar v d ty is upward, The average fo v B . 27.6 Magnet S perpendicular to d S S lume is ; a segment of conductor with length has volum n l S S velocidade de J volume is n; a segment ofcharge conductor with length vol lS, has SIlB F = = Drift velocity is directe F ! qv : B d ! dos directed to the left shown in the figure; s :arrasto B , S as mber of charges equal to The total force on all th nAl. F F = 1nAl21qv B2 = 1nqv A Current A of chargeof charges equal B d total force number toare The onSdall nAl.perpendicular, S StheFmagnitu transportadores carriers ar, the magnitude of the force is F = qv B. de carga s segment has magnitude d this segment hasismagnitude F ! I l : B We can derive an expression The force always perpendicular to bo What makes an electric S an expression for total force on all the moving c vd the density 25.3) the current is J = nqv . The length l dof conductor with cros d F =F1nAl21qv B2 = 1nqv A21lB2 currents (that is, whose = 1nAl21qv B2 = 1nqv A21lB2 dsame dright-ha d direction determined by the S cross-sectional l ctor with area A using the same la used in Eqs. (25.2) and (25.3) forces on the moving cho e can rewrite Eq. (27.16) as F om Eq. (25.3) the current density is J = nqv . The produc From Eq. (25.3) the current density is J = nqv . The prod Figure 27.27 illustra d d charge (Fig.ofq27.26). Hence this forceofcan be iseach segment of charg cond n; anumber ) and (25.3) Sectionvolume 25.1. The current-carrying co nt I,rent so we Eq. (27.16) as I, socan werewrite can rewrite Eq. (27.16) as ing-coil galvanometer t number of charges equal to nAl ment of conductor with length has volume and l Al If the conductor F = IlB he force on a single moving charge. We rep S S S forces on conductors. S this segment has magnitude F = IlB IlBall the moving s equal to nAl. The total forceFF=on gth inl aofcurrent-carrying conductor with cross-sectional arge conductor. S d l . The force dF on We can compute the f lfield along the wire in the direction of the curre S S Bnot perpendicular is not perpendicular the wire but m If the B field is to the wire but makes magnitude F = 1nA If the B field isJ not perpendicular toto the wire but makes an netic force F ! qv : B handle the situation theSsame way we did in Section 27. ndle the situation the same way we did in Section 27.2 situation the same way we did in Sectio From Eq. (25.3) the current den S S S S S S S F = 1nAl21qv B2 = 1nqv A21lB2 Only the component of B perpendicular to the wire (and to d d S ly the F component of B perpendicular to the wire (and to t dF ! I d l : B ! I l : B (magnetic force on rent I, so we can rewrite Eq. (27 the charges) exerts a force; this component is B = B sin omponent of B perpendicular to the wire ( ! charges) exerts a force; this component is B! = B sin f. S S S S S • Magnitude is F 5 IlB! 5 IlB sin f. S sobre um condutor com corrente Força magnética • Direction of F is given by the right-hand rule. S F B' 5 B sin f S S l B f Bi I 27.30 What is the total magnetic force on the conductor? Força magnética num condutor curvo y dFy S dF S B (out) S dl I u dl S F R I L L I du S u O dFx x I (in) Teste seu entendimento Which Qual orientation? orientação? A B r Switch chave barraConducting condutora bar trilhos Conducting condutores rails ❙ 😓😓 S F S B forces are reversed. + and magnetic fields called a velo he forces are reversed and magnetic fields are m, charge q, and speed v enters a region of space where v (a) enters a region of space where the electric Aplicações: seletor de velocidades S Schematic diagram of velocity selector with mass m, charge q, and spee ative. The electric field E is t tic fields are perpendicular to the particle’s velocity and to lar to the particle’s velocity and to each other. Fonte de partículas S S S figure. If q is positive, and magnetic fields are perpendic Source of charged particles carregadas (b) Free-body diagram for a positive part cmfield E is to thefield left,Band the magnetic nd the magnetic is into the plane field ofStheB is into the of velocity selector the magnetic force is t The electric field E is to the left, a q is positive, the electric force is to the left, with magnitu force is to the left, with magnitude tudes qE, and Only if for a charged E and B, a pa figure. If q is positive, the electr F ! qE F ! qvB particle has v ! E urce of charged particles E B ic force isS to theqvB. right, with magnitude qvB. For given fi with magnitude For given field magniBy the right-hand rule, equal dointhemagnitude; th S electric and ma v the magnetic force is to the right the force of the B field de B, a particular value of v theforces electric magnetic fo of for v the electric and magnetic willand beline straight with forces cancel. Allcon othe v on the charge points to tudes E and B, for a particular val S particles are deflected magnitude; the Btotal force is then travels zero, and -qE qvB particle = 0; solv e is then zero, and the particle in+ athe the right. By the right-hand rule, equal in magnitude; the total fo S S find ethewith constant velocity. For zero total force, gF = y. For zero total force, g F = 0, we need S y E y force of the B field The force straight of the E field line with constant veloc Bon=the0;v solving for the speed v for which there is no de speed for points which there is no deflection, we charge to on the charge points to the right. the left. - qE + qvB = 0; solving for the find S The force For a negative charge, E Only particles with spe E of the E field v of=both v the = charge points the (27.13) on to directions by the fields (Fig. 27.22 B forces are reversed. the left.B + + + + + + ticles having a particul 27.23 Thomson’s apparatus for me ingbeing the ratio the electron.bein e/minforEq. les equal towithout E>B can pass through without out (27.13), a ve E>Bwith canspeeds pass through deflected electrons pass straight throughcharge: the plates when Eq. (2 e eimpact. is theThe magnitude of the electron fied; combiningexperimento this with Eq. (27.14), we get 27.5 Applications Aplicações: de Thompson (elétron) ur+ 2 2eV 1 2 E e E 2eV mv = eV v = 1 V 2=or Electrons travel fromdo thecatodo cathode to the ascreen. Elétrons viajam para tela so = 2 gained kinetic energy 2 mv lostAelectric potential 2 m B equals A m + the feixe m 2VB de elétrons Electron beam 896 CHAPTER 27 Magnetic Field and Magnetic Forces 27.5 Applications of Motion of Charged Particles e is the magnitude of the electron charge: tela ratio Applications of Mo e> All the quantities on the right sideB can be 27.5 measured, soScreen the s pass between the plates P and P¿ and strike the screen 27.5 Applications of M 2eV e m mass can be determined. It is not possible to measure or sep 1 A 2 A" P mv = eV ormaterial v = that fluoresces (glows) (27.14) Catodo Cathode 2 ch is coated with a at t Anodes method, only their ratio. m A 1 2anodos P" Eelectric netic energy equals the lost potential mv 1 2 e>m The most significant aspect of Thomson’s measurement 2 ctrons pass straight through the plates when Eq. (27.1 gained energy equals the lost electric potential mv Entrekinetic as placas P e P' existem Between plates P and P" 2there agnitude of the electron charge: pass between the plates P and P¿ and strike the screen at the end found a single value for this quantity. It did not depend on the cat campos perpendiculares e – are mutually perpendicular, is thewith magnitude of the electron charge: ethis Eq. (27.14), we get uniform andagas Bmaterial fields. E eE B. h is uniformes coated with (glows) the point of the residual in the that tube,fluoresces or anything else at about the experime 2eV ronspendence pass straight through the plates when Eq. (27.13) is satisshowed that the particles in the beam, which we now cal 2eV 1 2 or 2 (27.14) = eV v = (27.14) mv = eV or v = E (27.14), e E 2eV his with Eq. we get a 2common constituent of all matter. Thus Thomson is credited wit m A A m so = = covery 2 m Bof a subatomic A m particle, the electron. 2VB 2 E e E 2eV e>m The most precise value of available as of this ass between the plates P and P¿ and strike the screen at thewriting end is en the plates P and P¿ and strike the screen at the end so = (27.15) = 2 is coated with a material that fluoresces (glows) atpoint the point of m m B A 2VB with a material that fluoresces (glows) at the of 11 e>m sonsonpass thestraight right through side can be measured, so the ratio o e>m = 1.7588201501442 * 10 C>kg the plates when Eq. (27.13) is satistraight through the plates when Eq. (27.13) is satisThis section describes several applications of the principles introduced in this chapter. Study them carefully, watching for applications of Problem-Solving Strategy 27.2 (Section 27.4). 27.22 (a) A velocity selector for S charged particles uses perpendicular E and S B fields. Only charged particles with v = E>B move through undeflected. (b) The electric and magnetic forces on a positive charge. The forces are reversed if the charge is negative. (a) Schematic diagram of velocity selector Source of charged particles q S v + S S + S + E + S B By the right-hand rule, S the force of the B field on the charge points to the right. S The force of the E field on the charge points to the left. Velocity SelectorS In a beam of charged particles produced by a heated cathode or a radioactive material, not all particles move with the same speed. Many applications, however, require a beam in which all the particle speeds are the same. Particles of a specific speed can be selected from the beam using an arrangement of electric and magnetic fields called a velocity selector. In Fig. 27.22a a charged particle with mass m, charge q, and speed v enters a region of space where the electric and magnetic fields are perpendicular to the particle’s velocity and to each other. S S The electric field E is to the left, and the magnetic field B is into the plane of the figure. If q is positive, the electric S force is to the left, with magnitude qE, and the magnetic force is to the right, with magnitude qvB. For given field magnitudes E and B, for a particular value of v the electric and magnetic forces will be equal in magnitude; the total force is then zero, and the particle travels in a straight line with constant velocity. For zero total force, g Fy = 0, we need - qE + qvB = 0; solving for the speed v for which there is no deflection, we find v = + + + For a negative charge, the directions of both forces are reversed. (b) Free-body diagram for a positive particle FE ! qE Only if a charged FB ! qvB particle has v ! E B do the electric and magnetic forces cancel. All other v particles are deflected. / 27.23 Thomson’s apparatus for measuring the ratio e/m for the electron. E B (27.13) Only particles with speeds equal to E>B can pass through without being deflected by the fields (Fig. 27.22b). By adjusting E and B appropriately, we can select particles having a particular speed for use in other experiments. Because q divides out in Eq. (27.13), a velocity selector for positively charged particles also works for electrons or other negatively charged particles. Thomson’s e/m Experiment In one of the landmark experiments in physics at the end of the 19th century, J. J. Thomson (1856–1940) used the idea just described to measure the ratio of charge to mass for the electron. For this experiment, carried out in 1897 at the Cavendish Laboratory in Cambridge, England, Thomson used the apparatus shown in Fig. 27.23. In a highly evacuated glass container, electrons from the hot cathode are accelerated and formed into a beam by a potential difference V between the two anodes A and A¿. The speed v of the electrons is determined by the accelerating + V Electrons travel from the cathode to the screen. + Electron beam Screen S B A Cathode A" Anodes P S E P" rection shown.sinOn is perpendicular to(b)the current >22 sin = 1IBa21b f2this side, B(27.22) (a) f as S on this Força e torque sobre uma espira de corrente e90°, force side has magnitude TheB twoispairs of forces acting on the loop cancel, so no net force acts on the loop. in the plane of the loop, and the nor- z S Screen Electron beam Electrons travel from the cathode to the screen. S S S to B (Fig. 27.31b). The torque is zero when is f However, the forces on the a sides of the loop F (F and 2F) produce a torque B = IaB z t 5 is (IBa)(b sinf) on the loop. e loop parallel or antiparallel to the field (Fig. S stable because the but torque is S the e ! Fequilibrium withythe position same magnitude opposite direction acts on I y B slightly from this position, the resulting S f is the angle frotated the loop, as shown in the figure. 𝜙 ângulo F! I = 180° between a vector toward The position is an f = 0°. f S S entre o vetor S direction normalwith to the loop ef displaced sides length b make an angle 190° f2 with the B B m x slightly from this position, normal S theS loop S and theàmagnetic S Fabout these the vectors ! F ¿; their magnitude SF¿ is B 90° 2rotation f F ¿ and field. espira e B sides mon Figure 27.31 shows f = 180°. I are 2F f S rce on the loop is zero,mEq. (27.22) ffor the torque 27.7 Force and Torque on a Current Loop 903 27.7 Force and Torque on a Current Loop 903 (equal to the perpendicular distance from the rotation axis to the line of action of perpendicular from due the rotation to the linemagnitude of action of sin f, sodistance the(equal force)to the is 1b>22 the torque to eachaxis force has 1b>22 sin f, the force) is so the torque due to each force has F1b>22 sin f. If we use Eq. (27.21) for F, the magnitude of the net torquemagnitude is F1b>22 sin f. If we use Eq. (27.21) for F, the magnitude of the net torque is t = 2F1b>22 sin f = 1IBa21b sin f2 (27.22) t = 2F1b>22 sin (27.22) S f = 1IBa21b sin f2 The torque is greatest when f = 90°, B is S in the plane of the loop, and the norS The torque is greatest when f to = B90°, B 27.31b). is in the The planetorque of theisloop, and the normal to this plane is perpendicular (Fig. zero when f is S to this plane perpendicular to Bis (Fig. 27.31b). The torque zero when f is or 180° and the is normal to the loop parallel or antiparallel toisthe field (Fig. 0° mal and the the loop is parallelposition or antiparallel thetorque field (Fig. 0° or 180° 27.31c). The value a stable equilibrium becausetothe is f normal = 0° is to 27.31c). value the stable slightly equilibrium because torque is f =loop 0° is zero there, The and when is arotated fromposition this position, thethe resulting zero there, when ittheback looptoward is rotated from this position, the resulting torque tends and to rotate position is an f slightly = 0°. The f = 180° torque equilibrium tends to rotate it back toward fslightly is an = 0°. The f = 180° unstable position; if displaced from position this position, the loop unstable equilibrium position; if displaced slightly from this position, the loop tends to move farther away from f = 180°. Figure 27.31 shows rotation about tends to move farther away from Figure 27.31 shows rotation about f = 180°. the y-axis, but because the net force on the loop is zero, Eq. (27.22) for the torque the y-axis, butchoice because the net force on the loop is zero, Eq. (27.22) for the torque is valid for any of axis. isThe valid for any choice of area A of the loop is axis. equal to ab, so we can rewrite Eq. (27.22) as The area A of the loop is equal to ab, so we can rewrite Eq. (27.22) as (magnitude of torque on a current loop) (27.23) t = IBA sin f (magnitude of torque on a current loop) (27.23) t = IBA sin f The product IA is called the magnetic dipole moment or magnetic moment of product called thesymbol magnetic dipole moment or magnetic moment of IA iswe theThe loop, for which use the Greek letter mu): m (the the loop, for which we use the symbol m (the Greek letter mu): m = IA (27.24) m = IA (27.24) It is analogous to the electric dipole moment introduced in Section 21.7. In terms analogous to the electric dipole momentloop introduced in Section 21.7. In terms of It m,isthe magnitude of the torque on a current is of m, the magnitude of the torque on a current loop is t = mB sin f (27.25) t = mB sin f (27.25) whereS f is the angle between the normal to the loop (the direction of the vector S where f isBthe angle between normal the loop direction of the vector area A2Sand . SThe torque tends the to rotate thetoloop in the(the direction of decreasing area A 2 and B . The torque tends to rotate the loop in the direction of decreasing f—that is, toward its stable equilibrium position in Swhich the loop lies in the f —that is, toward its stable equilibrium position in which the loop in the xy-plane perpendicular to the direction of the field B S (Fig. 27.31c). A lies current xy-plane perpendicular to the direction of the field B (Fig. 27.31c). A current loop, or any other body that experiences a magnetic torque given by Eq. (27.25), loop,called or anya other bodydipole. that experiences a magnetic torque given by Eq. (27.25), is also magnetic is also called a magnetic dipole. F¿ = IbB sin190° f b sin f - f2 = IbB cos(c) l to ab, so we can rewrite Eq. (27.22) as B S z (d to P nes of action of both forces lie along the y-axis. f m I eitude totalof force the loop is zero because the forces on opposite sid y F! B torque on on a current loop) (27.23) 2F B a pairs. I E P" S Magnetic Torque: Vector Form S Torque: WeMagnetic can also define a vectorVector magneticForm moment M with magnitude IA: This is shown S S S S S alsoThe define a vector moment with magnitude IA:plane This isofshown in We Fig.can 27.31. direction ofmagnetic M is defined to beMperpendicular to the the S in Fig. The direction of is defined to be perpendicular to the plane of the loop, with27.31. a sense determined byMa right-hand rule, as shown in Fig. 27.32. Wrap with sense determined by a the right-hand rule, Fig.direction 27.32. Wrap theloop, fingers ofayour right hand around perimeter of as theshown loop ininthe of fingersThen of your right hand around the perimeter of the loop in the direction of thethe current. extend your thumb so that it is perpendicular to the plane of the S S the its current. Then your thumb so that it isvector perpendicular to the plane of the loop; direction is extend the direction of M (and of the area A of the loop). The S S S S loop;isits direction is the direction of M (and of the vector area A ofthey the loop). The torque greatest when M and B are when are parS perpendicular and is zero S S S is zero when they are partorque is greatest when M and B are perpendicular and B are allel or antiparallel. In the stable equilibrium position, M and S parallel. S S allel or antiparallel. In thethis stable equilibrium position, and B vector are parallel. T, Swhich Finally, we can express interaction in terms of theMtorque T, which Finally, we can express this interaction in terms of the torque vector we used for electric-dipole interactions in SectionS 21.7. From Eq. (27.25) the S S we used for electric-dipole interactions in Section 21.7. From Eq. (27.25) the M : B , magnitude of T is equal to the magnitude of and reference to Fig. 27.31 S S S T M : B , magnitude of is equal to the magnitude of and reference to Fig. 27.31 shows that the directions are also the same. So we have shows that the directions are also the same. So we have S – B S + S I Sof gnetic dipole moment or magnetic moment S 2F! b 2F mbol (the Greek letter mu): m net force on a current loop in a uniform magnetic field is zero. Howe orque not in general equal to zero. m =is IA (27.24) S S S 27.32 The right-hand rule determines the27.32 directionThe of the magneticrule moment of a right-hand determines current-carrying This is also the of a the direction ofloop. the magnetic moment S direction of the loop’s area vector A; S current-carrying loop. This is also the S S M! vector equation. IA isS aof direction the loop’s area vector A; S M ! IA is a vector equation. I I I I S m S m S A S A I I I I greatest when they are antipara S This isS rrent-carrying loop. also the S The torque is m m The product is called the magnetic dipole moment or IA Finally, we can express this intera of the loop (F and 2F) produce a torque U as a function of orientatio rection of the loop’s area vector Ae ; energia potencial numa B S Torque espira when letter f 5 90° ( z use the symbol (the Greek m m ! IA is a vector equation.the loop, for which we F we used for electric-dipole interacti between the electric and magn the plane of the S S I T magnitude of is equal to the magni IA dipoleI inSman=electric field is T ! y B I x (direc showssponding that the directions are also theU potential energy is It is analogous to the electric dipole moment introduced inSS S S m I is loop T S! isM : B, S of m, the magnitude of the magnetic torque onSS afield current S S netic field. AB BT ! M : B (vec m sponding potential energy is x I S S S S I S B (b) 90° 2 f f . f f y I S F t = mB sin f # This resultthe2F isnormal directly analogous to t S where f is the angle between to the loop (the di S S z S S Uexerted = - MbyBan=electric - mB cos fE o torque field area A2 and B. The torque tends to rotate the loop in the dir (c) b sinS f The torque is maximal S is, toward its stable equilibrium position in Swhich B f—that z (direction normal S when f 5 90° (so B is in With this definition, U is zero w F Potential Energy for a Magne to loop) xy-planetheperpendicular to the direction of the field B (Fig Th plane of the loop). S m to the magnetic field. f5 loop, or any other body that experiences a magnetic torque g SI S When a magnetic dipole changes ori S I B S B fS 5 y(direction F! normal S Sto loop)B is also called axmagnetic dipole. work onBit. In an infinitesimal F angula I S Magnetic Torque: x Bi Loops pla I Magnetic Torque: Vector Form I S m The collection of rectangles 7.33 Although we haveS derived Eqs S 2F! I S S B b The Smagnitu can also define a vector magnetic moment M with xactly matchesS theWe irregular plane loop in 2F loop, all these relationships are 2F! S libr 2F he limit as the number of rectangles in Fig. 27.31. The directionnar of M is defined to approximated be perpendicul loop may be in u pproaches infinity loop, and the width of each with a sense determined by a right-hand rule, as shown (c) rectangular loops, as shown wh in 27.34 The torque T ! on M :the B on this nof exactly matches the irregular loopthe in sum magnetic field isplane simply of the torques individual loop, all these relationships are valid solenoid in a uniform magnetic field is he limit as the number of rectangles is noid with N turns in a uniform field B,may the magnetic is nar loop be directed straight into theapproximated page. Anmoment actual as clo approaches infinity and the width of each solenoid has many more turns, wrapped rectangular loops, as shown in Fig. 27 rectangle approaches zero. wh closely together. t = NIAB sin f al in the same clockwise sense, then thefief S d A planar current loop adjacent to each other mcancel, and the I gr any shape be where f isofthe anglecanbetween the axis of the solenoid and th f the boun are due to currents around wh S approximated by a field. The magnetic moment vector M is along the solenoid a valid for aS plane current loop of anyin set of rectangular I S greatest when loops. the solenoid axis is perpendicular to the magne so by M ! IA. Torque: espiras e bobinas when they are parallel. The effect this is tothis tend to r Weofcan alsotorque generalize whole ne I loops close together; the effect is sim into a position where its axis is parallel to the field. Solenoids I t is moment, the torque, and the28. potential sources of magnetic field, as we’ll discuss in Chapter lar An arrangement of particular inte The d’Arsonval galvanometer, described in Section 26.3, ma to wire, such as a coil wound on a circul cot netic torque on a coil carrying a current. As Fig. 26.14 shows, I closely spaced, the solenoid can be pr ap B is not uniform but is radial, solying the side thrusts on the coil are al I in planes at right angles to its cu lo Thef torque to(27.28) make the solenoid rotate 90°, lar to its plane. Thus the angle in tends Eq. is always re magnetic field is simply the sum of the O torque tende in a fazer o solenóide em S clockwise the plane of the page,girar aligning S S de is directly to the current, no matter what the 27.34 torque The torque T ! M : proportional B on this noid with N turns in a uniform field B magnetic moment m with field B. sentido horário no plano da figura, alinhando solenoid coil. in a uniform magnetic field is A restoring torque oproportional to the angular displacem directed straight into the page. An actual momento magnético 𝜇 com o campo B. t =ma by two which also serve as current leads solenoid provided has many more turns,hairsprings, wrapped of S S S S where f is the angle between the ax MAGNETIC FORCES Introdução Imageamento por ressonância nuclear permite o exame dos tecidos moles do pé que não são visíveis por raios X. No entanto os tecidos moles não são magnéticos. Como a técnica de RMN funciona? O paciente é colocado em um campo magnético de 1.5 T (10000 x o campo da Terra) . O núcleo de cada átomo de hidrogênio no tecido a ser examinado possui um momento de dipolo magnético que o alinha ao campo aplicado. A seguir o tecido é iluminado com ondas eletromagnéticas que retiram o átomo do alinhamento. A absorção de ondas eletromagnéticas é proporcional à quantidade de hidrogênio presente. Como o osso tem menos hidrogênio, o tecido mole fica "iluminado". Essa técnica é ideal para análise de tecidos humanos que não são visíveis em imagens de raios X. on in Fig. 27.39a. Brushes are aligned with commutator ow be (a) in its equisegments. ation. But here’s de rotação contact with both Eixo Rotation axis v Rotor rotor nce between the Rotor has turned 90°. Motor de corrente(b)contínua v I50 S BI S the rotor ends are attached N oop that is freeN to rotate about an axis; IS es are colored red andt blue for clarity.) The commutator escova Brush °. I v S m comutador (c) RotorCommutator has turned 180°. I + t50 B I S I I I m50 S t50 + v • Current flows into the red side of the rotor S BI S and out of the blue Nside. S I causes the • Therefore the magnetic torque S t rotor to spin counterclockwise. S S m m50 S S S I I + • Each brush is in contact with both commutator segments, so the current bypasses the rotor altogether. • No magnetic torque acts on the rotor.