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Single event upset on static random access memory devices due to spallation, reactor, and monoenergetic neutrons

Single event upset on static random access memory devices due to spallation, reactor, and monoenergetic neutrons
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摘要 This paper presents new neutron-induced single event upset(SEU) data on the SRAM devices with the technology nodes from 40 nm to 500 nm due to spallation, reactor, and monoenergetic neutrons. The SEU effect is investigated as a function of incident neutron energy spectrum, technology node, byte pattern and neutron fluence rate. The experimental data show that the SEU effect mainly depends on the incident neutron spectrum and the technology node, and the SEU sensitivity induced by low-energy neutrons significantly increases with the technology downscaling. Monte-Carlo simulations of nuclear interactions with device architecture are utilized for comparing with the experimental results. This simulation approach allows us to investigate the key parameters of the SEU sensitivity, which are determined by the technology node and supply voltage. The simulation shows that the high-energy neutrons have more nuclear reaction channels to generate more secondary particles which lead to the significant enhancement of the SEU cross-sections, and thus revealing the physical mechanism for SEU sensitivity to the incident neutron spectrum. This paper presents new neutron-induced single event upset(SEU) data on the SRAM devices with the technology nodes from 40 nm to 500 nm due to spallation, reactor, and monoenergetic neutrons. The SEU effect is investigated as a function of incident neutron energy spectrum, technology node, byte pattern and neutron fluence rate. The experimental data show that the SEU effect mainly depends on the incident neutron spectrum and the technology node, and the SEU sensitivity induced by low-energy neutrons significantly increases with the technology downscaling. Monte–Carlo simulations of nuclear interactions with device architecture are utilized for comparing with the experimental results. This simulation approach allows us to investigate the key parameters of the SEU sensitivity, which are determined by the technology node and supply voltage. The simulation shows that the high-energy neutrons have more nuclear reaction channels to generate more secondary particles which lead to the significant enhancement of the SEU cross-sections, and thus revealing the physical mechanism for SEU sensitivity to the incident neutron spectrum.
作者 Xiao-Ming Jin Wei Chen Jun-Lin Li Chao Qi Xiao-Qiang Guo Rui-Bin Li Yan Liu 金晓明;陈伟;李俊霖;齐超;郭晓强;李瑞宾;刘岩(State Key Laboratory of Intense Pulsed Radiation Simulation and Effect, Northwest Institute of Nuclear Technology)
出处 《Chinese Physics B》 SCIE EI CAS CSCD 2019年第10期387-396,共10页 中国物理B(英文版)
基金 Project supported by the National Natural Science Foundation of China(Grant Nos.11690040 and 11690043) the Foundation of State Key Laboratory of China(Grant Nos.SKLIPR1801Z and 6142802180304)
关键词 NEUTRON SRAM SEU CROSS-SECTION neutron SRAM SEU cross-section
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