超薄栅氮氧化物的击穿瞬态

S. Lombardo, F. Palumbo, J. Stathis, B. Linder, K. Pey, C. Tung
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引用次数: 2

摘要

研究表明,在较低电压的加速应力作用下,薄栅氧化物会发生递进击穿(BD)现象。这包括BD点的逐渐增长,以及作为栅极泄漏的结果,在运行条件下的时间可能是电路故障所需时间的很大一部分。在相应的电压范围内,研究了渐进式双相损伤点的I-V特性。该模型是基于对BD点物理结构的假设。这与直接透射电镜观测结果进行了比较。从电压和几何角度来看,导致双相流失控的实验条件,即从渐进双相流过渡到非常快速的双相流暂态。此外,还研究了不同材料对栅极双相瞬态的影响,以钨代替标准的多晶硅。
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Breakdown transients in ultra-thin gate oxynitrides
It has been shown that under accelerated stress at relatively low voltage thin gate oxides are subjected to the phenomenon of progressive breakdown (BD). This consists in a progressive growth of the BD spot, and as a consequence, of the gate leakage, in times that under operation conditions can be a large fraction of the time required for circuit failure. The I-V characteristics of the BD spot under progressive BD are investigated and modeled in the relevant range of voltages. The model is based on an assumption concerning the physical structure of the BD spot. This is compared to direct TEM observations. Experimental conditions in terms of voltages and geometry leading to BD runaway, i.e., the transition from progressive to very fast BD transient are shown and discussed. Moreover, the impact on the BD transient of a different material for the gate electrode is studied in the case of tungsten, used in place of the standard poly-Si.
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