High depth resolution characterization of the damage and annealing behaviour of ultra shallow As implants in Si

Ion Implantation Technology. 2002. Proceedings of the 14th International Conference on Pub Date : 1900-01-01 DOI:10.1109/IIT.2002.1258076

J. A. Van den Berg, D. Armour, M. Werner, S. Whelan, W. Vandervorst, T. Clarysse, E. Collart, R. Goldberg, P. Bailey, T. Noakes

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Abstract

The relationship between damage formation/annealing and As profile redistribution has been studied using low energy As implants into Si at 2.5 keV at doses between 3 × 1013 cm-2 and 2 × 1015 cm-2 at room temperature. Samples were annealed at temperatures between 600 and 1050°C. High depth resolution medium energy ion scattering (MEIS) and secondary ion mass spectrometry (SIMS) were used to characterise the damage build up and As profiles as a function of implant dose and anneal temperature. MEIS studies showed that damage does not accumulate according to the energy deposition function but proceeds from the surface inwards. This is ascribed to the accumulation of collision cascade produced interstitials that are attracted to and settle at initially the oxide/Si interface and later to the advancing amorphous/crystalline interface. Dopant depth profiles agreed well with TRIM calculations for doses ≥ 4 × 1014 cm-2. However, for lower doses the dopant was observed to have a profile nearer to the surface, due to trapping in the narrow surface damaged layer, in which it is more easily accommodated. Following epitaxial regrowth at 700°C, MEIS showed that -50 % of the As has moved into substitutional sites, consistent with activation and/or the formation of inactive AsnV clusters (n ≤ 4), while the remainder had segregated to and become trapped in a ≤1 nm wide layer, clearly located on the Si side of the oxide/Si interface. Very low energy SIMS analysis at normal incidence is able to resolve these ultra shallow peaks, including the As pileup following epitaxial regrowth. They also confirmed that As retention was complete during dose build up and annealing.

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Si中超浅As植入物损伤和退火行为的高深度分辨率表征

在室温下，以3 × 1013 cm-2和2 × 1015 cm-2的剂量在2.5 keV下低能As注入Si中，研究了损伤形成/退火与As分布重分布之间的关系。样品在600至1050°C的温度下退火。采用高深度分辨率中能离子散射(MEIS)和二次离子质谱(SIMS)来表征损伤累积和As谱随植入剂量和退火温度的变化。MEIS研究表明，损伤不按能量沉积函数累积，而是由表面向内进行。这归因于碰撞级联产生的间隙的积累，这些间隙最初被氧化物/硅界面吸引并沉淀，后来被推进的非晶/晶体界面吸引并沉淀。当剂量≥4 × 1014 cm-2时，掺杂剂深度曲线与TRIM计算结果吻合良好。然而，对于较低剂量的掺杂剂，由于被困在狭窄的表面损伤层中，更容易容纳，因此观察到其轮廓更接近表面。在700°C下外延再生后，MEIS显示- 50%的As进入取代位点，与激活和/或形成无活性AsnV簇(n≤4)一致，而其余的As则分离并被捕获在≤1 nm宽的层中，明显位于氧化物/硅界面的Si侧。在正常入射下的极低能量SIMS分析能够解决这些超浅峰，包括外延再生后的As堆积。他们还证实，在剂量积累和退火过程中，砷的保留是完全的。

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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Ion Implantation Technology. 2002. Proceedings of the 14th International Conference on

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