Temperature-Dependent Hydrogen Modulations of Ultra-Scaled a-IGZO Thin Film Transistor Under Gate Bias Stress

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY IEEE Open Journal of Nanotechnology Pub Date : 2024-04-08 DOI:10.1109/OJNANO.2024.3386123
Muhammad Aslam;Shu-Wei Chang;Min-Hui Chuang;Yi-Ho Chen;Yao-Jen Lee;Yiming Li
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Abstract

Recently, a-IGZO has advanced toward the next-generation electronics system because of its compatibility with complementary metal oxide semiconductor (CMOS) and back-end-of-line (BOEL) based systems. A systematic electrical characterization of a-IGZO TFT related to reliability issues, such as positive bias temperature stress (PBTS) and negative bias temperature stress (NBTS), would entitle its integration into novel electronics systems. Unexpectedly, PBTS is characterized by the transition of positive V th shift to negative V th shift (ΔV th , the positive shift followed by the stress and temperature activated negative shift). This transition is attributed to charge trapping/trap-site generations and hydrogen migration to the active layer. The ΔV th shift mechanism depends on the temperature and voltage stress. On the other hand, a negative ΔV th shift has been observed during the NBTS operation and could be attributed to the hole trapping at the interface of GI/IGZO. An effective suppression of the gate leakage current has also been observed during reliability tests. Simulation results reveal a pronounced potential at the edges of source and drain regions, and considered the origin of hydrogen migration into the IGZO layer. Thermal image results also reveal the strong temperature/potential distribution at the edges of the source/drain regions, indorsing the simulation results.
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栅极偏压应力下超标量 a-IGZO 薄膜晶体管的温度依赖性氢调制
最近,a-IGZO 因其与基于互补金属氧化物半导体(CMOS)和后端线(BOEL)系统的兼容性而向下一代电子系统迈进。对 a-IGZO TFT 的可靠性问题(如正偏压温度应力 (PBTS) 和负偏压温度应力 (NBTS))进行系统的电气特性分析,有助于将其集成到新型电子系统中。令人意想不到的是,PBTS 的特点是正 Vth 值漂移向负 Vth 值漂移的转变(ΔVth,正漂移后的应力和温度激活负漂移)。这种转变归因于电荷捕获/捕获位点生成以及氢迁移到活性层。ΔVth转变机制取决于温度和电压应力。另一方面,在 NBTS 工作期间观察到负 ΔVth 漂移,这可能是由于 GI/IGZO 接口处的空穴捕获所致。在可靠性测试中也观察到栅极漏电流得到了有效抑制。模拟结果显示,源极和漏极区域的边缘存在明显的电位,并认为这是氢气迁移到 IGZO 层的原因。热图像结果也显示了源极/漏极区域边缘强烈的温度/电位分布,证明了仿真结果。
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CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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