Title :
The Effects of Neutron Energy and High-Z Materials on Single Event Upsets and Multiple Cell Upsets
Author :
Clemens, Michael Andrew ; Sierawski, Brian D. ; Warren, Kevin M. ; Mendenhall, Marcus H. ; Dodds, Nathaniel A. ; Weller, Robert A. ; Reed, Robert A. ; Dodd, Paul E. ; Shaneyfelt, Marty R. ; Schwank, James R. ; Wender, Stephen A. ; Baumann, Robert C.
Author_Institution :
Dept. of Phys. & Astron., Vanderbilt Univ., Nashville, TN, USA
Abstract :
Neutron-induced charge collection data and computer simulations presented here show that the presence of high-Z materials, like tungsten, can increase the single event upset (SEU) and multiple cell upset (MCU)cross sections of high critical charge (Qcrit) devices exposed to the terrestrial neutron environment because of interactions with high energy ( >; 100 MeV) neutrons. Time-of-flight data and computer simulations presented here demonstrate that 14 MeV neutrons do not produce highly ionizing secondary particles. Thus, 14 MeV neutrons can only simulate the SEU response of 65 nm SRAM devices in the terrestrial neutron environment for devices with a Qcrit <; 27fC, and can simulate the 2-bit MCU response to within a factor of two only for very low Qcrit devices, <; 1.2 fC.Additionally, it is shown that 14 MeV neutrons cannot adequately simulate the 3 or more bit MCU response for typical 65 nm SRAM devices.
Keywords :
Monte Carlo methods; SRAM chips; neutron effects; semiconductor process modelling; tungsten; SRAM devices; W; computer simulations; electron volt energy 14 MeV; high critical charge devices; high energy neutrons; high-Z materials; highly ionizing secondary particles; multiple cell upset cross section; multiple cell upset response; neutron energy; neutron-induced charge collection data; single event upset cross section; single event upset response; size 65 nm; terrestrial neutron environment; time-of-flight data; Computer simulation; Data models; Monte Carlo methods; Neutrons; SRAM chips; Single event upset; Charge collection; GEANT4; Monte Carlo simulation; computer simulation; energy deposition; multiple bit upsets; neutron radiation effects; nuclear reactions; single event mechanism;
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2011.2171716
