光电子技术, 2019, 39 (1): 21, 网络出版: 2019-04-11  

H扩散掺杂源漏的自对准顶栅a-IGZO TFT制备工艺研究

Fabrication of Self-aligned Top-gate a-IGZO TFT with Source-drain Doped by Hydrogen Diffusion
作者单位
北京大学 薄膜晶体管与先进显示重点实验室, 广东 深圳 518055
摘要
采用氢(H)扩散掺杂源漏的方法对自对准顶栅a-IGZO TFT的制备工艺进行了研究。氢的扩散掺杂通过PECVD生长SiNx钝化层而实现。实验结果显示, 在栅电极图形化后, 是否继续进行栅介质刻蚀对器件性能有较大影响。对刻蚀了SiO2栅介质层的器件, 发现其泄漏电流较大, 这可能是由于有源层侧壁的刻蚀残留物导致的; 短沟道器件阈值电压偏负且在经过退火后迁移率减小, 则是由于严重的H横向扩散导致的。对未刻蚀SiO2栅介质层的器件, 发现其阈值电压相对偏正, 应该是因为SiO2栅介质对H的掺杂有一定的阻挡作用, 导致H的横向扩散得到了抑制; 器件在经过退火后迁移率上升, 开态电流增大, 应该是因为未刻蚀栅介质中的H热扩散到下方的源漏区域, 降低了源漏电阻。
Abstract
The fabrication of self-aligned top gate a-IGZO TFT with source-drain doped by hydrogen diffusion was studied. The doping of hydrogen was achieved during the growth of SiNx passivation layer by PECVD. The experimental results show that the performance of the device is greatly affected by the option for the gate dielectric etching following the gate electrode patterning. For the devices with gate dielectric layer etched, it is found that the leakage current is large, which may be caused by the etching residue on the side wall of active layer; The VTH of short channel devices is negative and the mobility decreases after annealing, which is caused by the deep H lateral diffusion. For the devices without gate dielectric layer etched, it is found that the VTH of devices is positive, because of the suppression of H lateral diffusion thanks to the inhibiting effect of SiO2 gate dielectric on H doping.The on-state current and mobility of devices increases after annealing, which may be due to the entrance of H in gate dielectric to the source and drain area by thermal diffusion, reducing resistance of source and drain area.

付海时, 彭昊, 张晓东, 张盛东. H扩散掺杂源漏的自对准顶栅a-IGZO TFT制备工艺研究[J]. 光电子技术, 2019, 39(1): 21. FU Haishi, PENG Hao, ZHANG Xiaodong, ZHANG Shengdong. Fabrication of Self-aligned Top-gate a-IGZO TFT with Source-drain Doped by Hydrogen Diffusion[J]. Optoelectronic Technology, 2019, 39(1): 21.

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