Ultra-shallow Junction Formed by Plasma Doping and Laser Annealing

2006 14th IEEE International Conference on Advanced Thermal Processing of Semiconductors Pub Date : 2006-10-01 DOI:10.1109/RTP.2006.367985

S. Heo, H. Hwang

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引用次数: 1

Abstract

We investigated ultra-shallow junction prepared by plasma doping (PLAD) and laser annealing (LA). Although PLAD is promising doping technology for the sub-45nm technology node due to the high dose rate at low energy, it has problems which is related with hydrogen or fluorine. The implanted hydrogen generally increases damage in the Si substrate. The fluorine also retards dopant activation and increases dopant deactivation during post-annealing step. Conventional one step annealing processes such as rapid thermal annealing (RTA) or excimer laser annealing (LA) are not effective method for high dopant activation. To minimize the effect of hydrogen or fluorine, we propose additional pre-annealing followed by conventional laser annealing. By employing low temperature pre-annealing, we can improve electrical characteristics such as low sheet resistance, high activation rates, shallow junction depth and reduced dopant deactivation. The improvement can be explained by reduced defect density and out-diffusion of fluorine or hydrogen which in turn enhances dopant activation during ELA

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等离子体掺杂与激光退火形成的超浅结

研究了等离子体掺杂(PLAD)和激光退火(LA)制备的超浅结。PLAD因其在低能量下的高剂量率是在sub-45nm技术节点上很有前途的掺杂技术，但存在与氢或氟相关的问题。注入的氢通常会增加硅衬底的损伤。在退火后的步骤中，氟还延缓了掺杂剂的活化并增加了掺杂剂的失活。传统的一步退火工艺，如快速热退火(RTA)或准分子激光退火(LA)都不是高掺杂激活的有效方法。为了尽量减少氢或氟的影响，我们建议在常规激光退火之后进行额外的预退火。通过采用低温预退火，我们可以改善电学特性，如低片电阻，高激活率，浅结深度和减少掺杂失活。这种改善可以通过降低缺陷密度和氟或氢的外扩散来解释，这反过来又增强了ELA过程中掺杂剂的活化

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2006 14th IEEE International Conference on Advanced Thermal Processing of Semiconductors

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