Energy dependence of vacuum-ultraviolet-induced radiation damage to electronic materials

J. Lauer, J. Shohet, R. Hansen, R. D. Bathke, B. Grierson, G. Upadhyaya, K. Kukkady, J. Kalwitz
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引用次数: 1

Abstract

Dielectric charging plays a key role in processing damage of semiconductor devices. VUV radiation with energies in the range of 4-30 eV can induce charge on electronic materials. Radiation charging of Si wafers coated with 3000A of Si/sub 3/N/sub 4/ from synchrotron VUV exposure with photon fluxes in the range of 10/sup 9/-10/sup 13/ photons/sec cm/sup -2/ were measured with a Kelvin probe. The photoemission current and substrate voltage were monitored during each exposure. The integral of photoemission current was compared to the net charge measured with the Kelvin probe for VUV photon energies between 7-21 eV. The net charge induced on the dielectric results from both photoemission (which saturates for long exposure times) as well as from charge carriers generated within the dielectric. Since the threshold photon energy for photoemission is higher than that for electron-hole pair production, it is seen that photoemission can be minimized if the photon energies are below the threshold energy.
真空紫外线对电子材料辐射损伤的能量依赖性
介质充电在半导体器件的加工损伤中起着关键作用。能量在4 ~ 30ev范围内的VUV辐射可以在电子材料上诱导电荷。用开尔文探针测量了在同步加速器VUV照射下,在10/sup 9/-10/sup 13/光子/秒cm/sup -2/范围内涂覆3000A Si/sub 3/N/sub 4/的硅晶片的辐射电荷。在每次曝光过程中监测光发射电流和衬底电压。在7 ~ 21 eV的VUV光子能量范围内,用开尔文探针测量了光发射电流积分和净电荷。在电介质上产生的净电荷来自于光发射(在长曝光时间内饱和)以及电介质内产生的载流子。由于光发射的阈值光子能量高于产生电子-空穴对的阈值光子能量,因此可以看出,如果光子能量低于阈值能量,则可以使光发射最小化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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