等离子体掺杂:适用于65nm及以上技术节点的具有生产价值的解决方案

Extended Abstracts of the Fifth International Workshop on Junction Technology Pub Date : 2005-06-07 DOI:10.1109/IWJT.2005.203885

Z. Fang, E. Arevalo, T. Miller, H. Persing, E. Winder, V. Singh

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引用次数: 0

摘要

65纳米及以上的先进逻辑和DRAM器件将需要在增加剂量的情况下减少结深度和聚层厚度。由于空间电荷效应的影响，目前的波束线技术在这一转变过程中将遭受吞吐量下降的影响。等离子体掺杂是一种具有良好特性的束线技术替代方案，可以满足<65nm ITRS技术节点的掺杂要求。这是在优越的吞吐量水平上完成的，这在很大程度上对能量不敏感。等离子体掺杂工具设计的简单性和成熟的过程控制特性为该技术的生产价值提供了广阔的前景。瓦里安的PLAD工具展示了先进的逻辑USJ SDE/SD形成以及先进的DRAM多晶硅和SD掺杂能力。在本文中，我们展示了植入和退火的SIMS概况，以突出用于PMOS晶体管制造的PLAD系统的亚kv掺杂能力及其对R/sub s/ vs. X/sub J/优点值的影响。透射电镜数据也将显示，在高标称剂量植入后，没有残余损伤，这与在PLAD掺杂器件上观察到的低结漏非常吻合。上述工艺的生产价值被证明具有均匀性、可重复性、金属纯度和颗粒性能，可与光束线植入物相媲美。

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Plasma doping: production worthy solution for 65nm and beyond technology nodes

65nm and beyond advanced logic and DRAM devices will require decreasing junction depths and poly thickness at increasing doses. Present beam-line technology will suffer decreasing throughput during this transition as a result of space charge effects. Plasma doping is a well characterized alternative to beam-line technology that meets the doping requirements for <65nm ITRS technology nodes. This is accomplished at superior throughput levels which are largely energy insensitive. The simplicity of the plasma doping tool design and maturing process control features offer a promising future for production worthiness of this technique. Varian's PLAD tool has demonstrated advanced logic USJ SDE/SD formation as well as advanced DRAM poly and SD doping capability. In this paper we present as-implanted and annealed SIMS profiles to highlight the sub-kV doping capability of the PLAD system for PMOS transistor fabrication and its impact on the R/sub s/ vs. X/sub J/ figure of merit. TEM data will also be presented to show lack of residual damage after a high nominal dose implant which agrees well with low junction leakage observed on PLAD doped devices. The production worthiness of the processes mentioned above is demonstrated with uniformity, repeatability, metals purity and particle performance comparable to that attainable with beam-line implants.

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Extended Abstracts of the Fifth International Workshop on Junction Technology

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