The EPD/Suprathermal Ion Spectrograph (SIS) For Solar Orbiter
Transcription
The EPD/Suprathermal Ion Spectrograph (SIS) For Solar Orbiter
The Suprathermal Ion Spectrograph (SIS) for the Solar Orbiter spacecraft J. 1 Köhler , R. F. 1 Wimmer-Schweingruber , 2 Mason , G. M. 2 3 G. C. Ho , J. R-Pacheco K. 2 Tyagi , H. 2 Seifert , 1IEAP, Christian-Albrechts-University Kiel, Germany, 2Johns Hopkins University Applied Physics Laboratory, United States 3Space Research Group/University of Alcalá Abstract Instrument concept The SIS instrument is part of the Energetic Particle Detector (EPD) suite for the Solar Orbiter spacecraft. The EPD will provide a full range of measurements for energetic electrons, energetic protons, and energetic heavy ions, where SIS will provide observations of He-Fe for an energy range from just above the solar wind up to several MeV/nucleon. SIS identifies particle species and energy by time-offlight by energy technique, and is based on the ACE/ULEIS design. Particles are detected when they pass through the entrance foil and deposit their energy in one solid state detector pixel at the back of the instrument. When the ion passes through the entrance, mid, and detectorfoils secondary electrons are emitted, accelerated to ~1 kV, and directed via isochronous mirrors onto microchannel plate stacks to provide a time-off-light measurement. The very high mass resolution of m/σm ~ 50 will allow SIS to measure particle populations with 3He/4He ratios down to <1% • Particles are detected when they pass through the entrance foil and trigger one of the SSD pixels in the array at the back • Secondary electrons are emitted when the ion passes the entrance, middle and detector foils • The electrons are accelerated up to ~ 1kV and directed via electrostatic mirrors onto microchannel plates (MCP) • The Start-1, Start-2 and Stop signals provide two independent time-of-flight measurements (flight paths length 21.0 and 11.2 cm) • Particle speed is obtained from the velocity measurement: v = l/t. • The SSD measures the residual energy, E, of the ion • The energy E, time-of-flight t, and known flight path in the telescope l, are combined to give the particle mass m 2 E (t / l ) 2 The Suprathermal Ion Spectrograph (SIS) is a sensor that is part of the Energetic Particle Detector (EPD) suite for the Solar Orbiter Spacecraft. The EPD suite’s sensors are designed to provide the full range of measurements for energetic electrons, energetic protons, and energetic heavy ions. • SIS has large geometry factor for studying the ambient suprathermal populations • Door closes to limit aperture during high intensity periods • Electrostatic mirrors give precise secondary electron time required for high mass resolution SIS has one sunward looking and one rearward facing telescope sharing a single electronics box; mounted on –y panel of Solar Orbiter in the permanent shade of the sunshield. SIS as a part of the EPD suite SIS provides composition measurements for He-Fe from the suprathermal range up through ~10 MeV/nucleon, with protons, electrons, and higher energies covered by other sensors in the Energetic Particle Detector (EPD) Suite (Pacheco et al. 2008). Science Objectives Suprathermal ion studies on Solar Orbiter: Key Relevant Science Goals from the "Red Book": 2.3 How do solar eruptions produce energetic particle radiation that fills the heliosphere? • How and where are energetic particles accelerated at the Sun? • How are energetic particles released from their sources and distributed in space and time? • What are the seed populations for energetic particles? Acceleration - seed population? Material in coronal loops? (high T, Ferich?) Ions encountering shock? Bulk solar wind? “Flare” particles? Suprathermal ions? -- what properties? Adapted from Marty Lee, ApJS, 158, 2005 Oxygen fluence at 1 AU from solar wind through galactic cosmic ray energy range. SIS energy range for heavy ions is shown as filled red box. SIS covers the suprathermal energy range and the principal energy ranges for impulsive SEPs, shocks, etc. (Fluence figure adapted from Mewaldt et al., 2001). • telescope high resolution design based on ACE/ULEIS • high heritage electronics design based on current projects • meets or exceeds all Solar Orbiter requirements for energy range, mass resolution EPD fields of view in the spacecraft frame of reference. Mean Parker spiral direction is marked as a black star. The two shaded areas correspond to the variability of the field at 1 AU in a slow-wind stream (green) and at 0.225 AU in a fast stream (gray). There are many important sources of suprathermals -- not just solar wind: • Solar wind suprathermal tail • Pick up ions • Remnant material from ...Impulsive SEPs ...CIRs ...Shock events ...Bow shocks SIS will determine the constituents and properties of the unexplored suprathermal ion pool within 1 AU SIS will provide the critical link between the energetic particles and the bulk solar wind measurements SIS will probe the energy range where differences in solar wind and energetic particle composition begin, in order to explore the reason for these differences Impulsive events will be detected primarily by SIS, since most produce particles of energy ~1 MeV/nucleon or less SIS will provide observational data for magnetic connection to reconnection sites low in the corona SIS will provide the low energy SEP spectral segment required to identify “breaks” in the large SEP event particle spectra observed by LET and HET SIS will provide high time resolution CME-shock associated energetic particle spectra close to or even within the acceleration site ...Inner source … others? Contact: Dr. Jan Köhler Institute of Experimental and Applied Physics Christian-Albechts-Universität zu Kiel Leibnizstr. 11, 24118 Kiel, Germany Tel.: +49-431-880-3944 Fax: +49-431-880-3968 [email protected] www.ieap.uni-kiel.de/et Poster download: Suprathermal Ion Spectograph for Solar Orbiter mission • SIS is an ESA facility instrument • SIS is a portion of the Energetic Particle Detector suite, Dr. Javier R.-Pacheco, Univ of Alcalá, PI • SIS is to be provided by Christian-Albrechts Univ., Kiel, in collaboration with the Johns Hopkins Univ./Applied Physics Laboratory • Dr. R. F. Wimmer-Schweingruber is the SIS PI