Electrical and Data-Retention Characteristics of Two-Terminal Thyristor Random Access Memory

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Hyangwoo Kim;Hyeonsu Cho;Byoung Don Kong;Jin-Woo Kim;Meyya Meyyappan;Chang-Ki Baek
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引用次数: 1

Abstract

Two-terminal (2-T) thyristor random access memory (TRAM) based on nanoscale cross-point vertical array is investigated in terms of lengths and doping concentrations of storage regions for long data retention time (Tret). For high device scalability and low program voltage (VP), lengths of the storage regions are determined by the sum of depletion widths of N- and P-storage regions. When doping concentrations of two storage regions are equal to each other at 10 18 cm -3 , 2-T TRAM exhibits the longest Tret of 100 ms and the lowest impact ionization of the device can suppress various reliability issues such as hot carrier injection and junction degradation. Although Tret of 2-T TRAM can be reduced from 100 ms to 1.5 ms due to decreased read voltage with operating temperature rising from 300 K to 360 K, Tret can be further improved to >10 s by applying standby voltage (Vstandby). The effective way to set minimum Vstandby is presented using the IA-VA characteristics with 1000-s fall time. Moreover, the optimal Vstandby is set to 0.60 V by considering disturbance in array operation. Consequently, the proposed design and operation guidelines can provide a pathway to realize nanoscale 2-T TRAM for capacitor-less 4F 2 1T DRAM technology.
双端晶闸管随机存取存储器的电气特性和数据保持特性
研究了基于纳米级交叉点垂直阵列的双端晶闸管随机存取存储器(TRAM)的存储区长度和掺杂浓度对长数据保留时间(Tret)的影响。对于器件的高可扩展性和低程序电压(VP),存储区域的长度由N-和p -存储区域的耗尽宽度的总和决定。当两个存储区域的掺杂浓度在1018 cm-3处相等时,2-T TRAM的最长Tret为100 ms,器件的最低冲击电离可以抑制各种可靠性问题,如热载流子注入和结退化。虽然当工作温度从300 K上升到360 K时,由于读取电压降低,2-T TRAM的Tret可以从100 ms降低到1.5 ms,但通过施加备用电压(Vstandby), Tret可以进一步提高到>10 s。利用跌落时间为1000秒的IA-VA特性,提出了设置最小待机时间的有效方法。考虑到阵列运行中的干扰,将最佳备用电压设置为0.60 V。因此,所提出的设计和操作指南可以为实现无电容4F2 1T DRAM技术的纳米级2-T TRAM提供途径。
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来源期刊
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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