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SUN Haohan, GUO Gang, LIU Jiancheng, ZHANG Zheng, ZHANG Fuqiang, ZHAO Yongle, YANG Zhi. Study on Single Ion Hit System Based on Heavy Ion Micro-beam[J]. Atomic Energy Science and Technology, 2023, 57(10): 2034-2040. DOI: 10.7538/yzk.2022.youxian.0887
Citation: SUN Haohan, GUO Gang, LIU Jiancheng, ZHANG Zheng, ZHANG Fuqiang, ZHAO Yongle, YANG Zhi. Study on Single Ion Hit System Based on Heavy Ion Micro-beam[J]. Atomic Energy Science and Technology, 2023, 57(10): 2034-2040. DOI: 10.7538/yzk.2022.youxian.0887
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Study on Single Ion Hit System Based on Heavy Ion Micro-beam

  • China Institute of Atomic Energy, Beijing 102413, China

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  • As a key technology to study the physical mechanism of single event effects (SEEs) and to identify the sensitive area of microelectronic devices, heavy ion micro-beam irradiation has been paid more and more attention by researchers. Single ion hit (SIH) is an important part of heavy ion micro-beam irradiation, which could reduce the number of incident ions to just one through a series of monitoring and control methods. Owing to this background, the single ion hit (SIH) system was established based on the pinhole heavy ion micro-beam facility in Beijing HI-13 tandem accelerator. To realize single ion hit, it is necessary to cut off the beam current immediately after monitoring the first ion incidence, so as to avoid the next ion passing through the beam switch. Therefore, the beam monitoring device is important to SIH system. The beam monitoring device consists of a 7 nm carbon film, a secondary electron detector and a beam monitoring computer. There is a fixed coefficient K between the number of ions incident on the device and the number of secondary electrons collected by the secondary electron detector. According to the value of K, the number of incident ions can be controlled by the number of secondary electrons. Through the analysis of the potential factors affecting the SIH performance, the theoretical reference formula of factors that affect the accuracy of SIH was given. The three main factors, K, beam intensity and shutter time were experimentally. The results show that the accuracy of this SIH system can reach 90% when the shutter time is 60 ms and the beam intensity is low. At the same time, lower beam intensity and shorter shutter tim are conducive to continuously improving the SIH performance. However, due to the technology limitation of the accelerator, the intensity and uniformity of the beam cannot be achieved at the same time. If the current intensity is too low, the uniformity will become much worse. Therefore, the single ion hit experiment should be carried out when the beam is relatively uniform and the K is stable. At last, the SIH system was applied to 28 nm SRAM device irradiation to reduce the interference of multiple ion incidence. Different patterns and the distribution of multiple cell upsets (MCUs) induced by the single ion were obtained, which verified the availability of the system in the research of radiation effect mechanism of nano devices. Based on the SIH system, it can be determined that all the MCUs are real events without obtaining chip layout information or post processing of data, which could improve data analysis efficiency and provide more real-time information for the experimental personnel.
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    • References (19)
  • [1]
    WALLMARK J T, MARCUS S M. Minimum size and maximum packing density of nonredundant semiconductor devices[J]. Proceedings of the IRE, 1962, 50(3): 286-298.
    [2]
    KOBAYASHI D. Scaling trends of digital single-event effects: A survey of SEU and SET parameters and comparison with transistor performance[J]. IEEE Transactions on Nuclear Science, 2020, 68(2): 124-148.
    [3]
    FLEETWOOD D M. Radiation effects in a post-Moore world[J]. IEEE Transactions on Nuclear Science, 2021, 68(5): 509-545.
    [4]
    HEIDEL D F, BAPST U H, JENKINS K A, et al. Ion microbeam radiation system[J]. IEEE Transactions on Nuclear Science, 1993, 40(2): 127-134.
    [5]
    FISCHER B E, HEISS M, CHOLEWA M. About the art to shoot with single ions[J]. Nuclear Instruments and Methods in Physics Research B, 2003, 210: 285-291.
    [6]
    OIKAWA M, SATOH T, SAKAI T, et al. Focusing high-energy heavy ion microbeam system at the JAEA AVF cyclotron[J]. Nuclear Instruments and Methods in Physics Research B, 2007, 260(1): 85-90.
    [7]
    郭刚,许谨诚,李志常,等. 北京HI-13串列加速器上单粒子效应辐射装置简介[C]∥全国核结构大会暨全国核结构专题讨论会. 北京:中国物理学会中国核学会,2006.
    [8]
    SHENG Lina, SONG Mingtao, GAO Daqing, et al. Study of the aberrations of the IMP heavy ion microbeam irradiation system[J]. Chinese Physics C, 2009, 33(S2): 26-29.
    [9]
    GUO Jinlong, DU Guanghua, BI Jinshun, et al. Development of singleevent-effects analysis system at the IMP microbeam facility[J]. Nuclear Instruments and Methods in Physics Research B, 2017, 404: 250-253.
    [10]
    SCHONE H, WALSH D S, SEXTON F W, et al. Time-resolved ion beam induced charge collection (TRIBICC) in micro-electronics[J]. IEEE Transactions on Nuclear Science, 1998, 45(6): 2544-2549.
    [11]
    李丽丽,汪栋,刘夏杰,等. 65 nm双阱CMOS静态随机存储器多位翻转微束及宽束实验研究[J]. 原子能科学技术,2018,52(7):1326-1334.
    LI Lili, WANG Dong, LIU Xiajie, et al. Micro-beam and broad-beam experimental research of multiple-cell upset in 65 nm dual-well CMOS SRAM[J]. Atomic Energy Science and Technology, 2018, 52(7): 1326-1334(in Chinese).
    [12]
    CHI Y, SONG R, SHI S, et al. Characterization of single-event transient pulse broadening effect in 65 nm bulk inverter chains using heavy ion microbeam[J]. IEEE Transactions on Nuclear Science, 2016, 64(1): 119-124.
    [13]
    史淑廷,郭刚,王鼎,等. 单粒子翻转二维成像技术[J]. 信息与电子工程,2012,10(5):608-612.
    SHI Shuting, GUO Gang, WANG Ding, et al. Technique of single event upset mapping[J]. Information and Electronic Engineering, 2012, 10(5): 608-612(in Chinese).
    [14]
    MARTINELLA C, ZIEMANN T, STARK R, et al. Heavy-ion microbeam studies of single-event leakage current mechanism in SiC VD-MOSFETs[J]. IEEE Transactions on Nuclear Science, 2020, 67(7): 1381-1389.
    [15]
    EVANS A, ALEXANDRESCU D, FERLET-CAVROIS V, et al. Techniques for heavy ion microbeam analysis of FPGA SER sensitivty[C]∥2015 IEEE International Reliability Physics Symposium. IEEE, 2015: SE.6.1-SE.6.6.
    [16]
    SATOH T, KOKA M, KADA W, et al. Real-time single-ion hit position detecting system for cell irradiation[J]. Nuclear Instruments and Methods in Physics Research B, 2014, 332: 242-244.
    [17]
    沈东军. 重离子微束辐照装置的研制[D]. 北京:中国原子能科学研究院,2004.
    [18]
    TAUSCH H J. Simplified birthday statistics and hamming EDAC[J]. IEEE Transactions on Nuclear Science, 2009, 56(2): 474-478.
    [19]
    WIRTHLIN M, LEE D, SWIFT G, et al. A method and case study on identifying physically adjacent multiple-cell upsets using 28 nm, interleaved and SECDED-protected arrays[J]. IEEE Transactions on Nuclear Science, 2014, 61(6): 3080-3087.
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