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Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays. Christina L. Howe 1 , Robert A. Weller 1 , Robert A. Reed 1 , Brian D. Sierawski 2 , Paul W. Marshall 3 , Cheryl J. Marshall 4 ,
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Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays Christina L. Howe1, Robert A. Weller1, Robert A. Reed1, Brian D. Sierawski2, Paul W. Marshall3, Cheryl J. Marshall4, Marcus H. Mendenhall5, Ronald D. Schrimpf1, and J. E. Hubbs6 1. Department of Electrical Engineering and Computer Science, Vanderbilt University, Nashville, TN 37235 2. Institute for Space and Defense Electronics, Vanderbilt University, Nashville, TN 37235 3. Consultant, Brookneal, VA 24528 4. NASA-GSFC, Greenbelt, MD 20771 5. Free-Electron Laser Center, Vanderbilt University, Nashville, TN 37235 6. Ball Aerospace & Technologies Corp., Albuquerque, NM 87117
Background Motivation Experimental Setup Modeling Description Results Simulation compared with experimental results Contribution from reaction mechanisms Event rate calculation Conclusions Outline Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Focal plane arrays (FPAs) often used on satellites planned for long orbits in harsh proton environments FPAs Advantages Flexible, reliable, low cost, high-density resolution, on-chip signal processing, and more radiation tolerant to protons than charge coupled devices (CCDs) Detector Array In In In ROIC Background Basic hybrid FPA Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Proton events contribute to device noise floor Better understanding of how radiation-induced energy deposition occurs will improve prediction techniques Accurate modeling helps predict on-orbit response We will show a high-fidelity prediction method based on Monte Carlo simulations and a mathematical model Motivation http://sohowww.nascom.nasa.gov/gallery/Movies/flares.html Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Experimental Setup • Hybrid FPA consisting of a silicon p-i-n 128 × 128 detector array with hardened CMOS readout integrated circuit (ROIC) • Full radiometric characterizations were performed • Dark current, noise, responsivity, and sensitivity • Irradiated with 63 MeV protons at 45° • Biased to 15V resulting in full depletion • Exposed at 233 K Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
63 MeV Proton Sensitive Volume 45° Modeling Description • MRED (Monte Carlo Radiative Energy Deposition), a GEANT4 based tool, used for simulation • TCAD simulations revealed RPP assumption was sufficient to estimate device response to radiation Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Modeling Description • Each event in Monte Carlo simulation represents only one primary particle hit one pixel, but… • Non-negligible probability of multiple hits on a single pixel (pile up) exists • Non radiation induced noise in experimental data Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Pile Up µ = 0.08 σNOISE = 3 After Pile Up Before Pile Up Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Results Statistical floor of experimental data Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Does not predict occurrence of large energy depositions Does not predict shape of curve Constant-LET and Path Length Distribution Calculation Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Reaction Mechanisms • Nuclear reactions dominate above 500 keV • Coulomb scattering does not contribute significantly here Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Event Rate Simulations • Proton environments from CREME • GEO – peak five minutes and worst week • ISS – space station orbit, apmin8 Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
GEO Event Rate Simulations Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
ISS Event Rate Simulations Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu
Conclusions • The on-orbit response can be predicted with greater detail than available through experiment at energies greater than 700 keV • Energy events greater than 130 keV are not predicted by path length calculation for this device • Nuclear reactions dominate the event rate at energies greater than 3 MeV Measurement and Simulation of the Variation in Proton-Induced Energy Deposition in Large Silicon Diode Arrays christina.l.howe@vanderbilt.edu