Bavley Guerguis , Ramya Cuduvally , Richard J.H. Morris , Gabriel Arcuri , Brian Langelier , Nabil Bassim
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引用次数: 0
摘要
本研究利用原子探针断层扫描(APT)技术研究了表面电场对硼(B)植入硅(Si)量化精度的影响。在分析过程中,硅电荷态比(CSR(Si) = Si2+/Si+)被用来间接测量平均顶点电场。对于一定范围的电场,通过 APT 确定的总植入剂量和深度剖面形状的准确性与美国国家标准与技术研究院标准参考材料 2137 进行了对比评估。此外,还检测了检测到的 B 的径向(非)均匀性。在较高的表面电场(即较大的 CSR(Si))下,测定的 B 剂量与认证剂量趋同。此外,深度剖面的形状也趋向于二次离子质谱法得出的形状。这一改进与解吸图显示的更均匀的辐射 B 分布相吻合。相反,对于较低的表面电场(即较低的 CSR(Si)),B 剂量被明显低估,深度剖面被人为拉伸。解吸图还显示,探测器中心周围的 B 发射极不均匀,据信这是 B 在样品顶端表面迁移的假象。就使用 APT 对半导体器件进行常规研究而言,这些结果说明了量化伪影的潜在来源及其在不同操作条件下的严重程度,从而为实现准确、可重复测量的最佳实践提供了途径。
The impact of electric field strength on the accuracy of boron dopant quantification in silicon using atom probe tomography
This study investigates the impact of the surface electric field on the quantification accuracy of boron (B) implanted silicon (Si) using atom probe tomography (APT). The Si Charge-State Ratio (CSR(Si) = Si2+/Si+) was used as an indirect measure of the average apex electric field during analysis. For a range of electric fields, the accuracy of the total implanted dose and the depth profile shape determined by APT was evaluated against the National Institute of Standards and Technology Standard Reference Material 2137. The radial (non-)uniformity of the detected B was also examined. At a higher surface electric field (i.e., a greater CSR(Si)), the determined B dose converges on the certified dose. Additionally, the depth profile shape tends towards that derived by secondary ion mass spectrometry. This improvement coincides with a more uniform radial B distribution, evidenced by desorption maps. In contrast, for lower surface electric fields (i.e., a lower CSR(Si)), the B dose is significantly underestimated, and the depth profile is artificially stretched. The desorption maps also indicate a highly inhomogeneous B emission localized around the center of the detector, which is believed to be an artifact of B surface migration on the tip of the sample. For the purposes of routine investigations of semiconductor devices using APT, these results illustrate the potential origin of quantification artifacts and their severity at different operating conditions, thus providing pathways towards best practices for accurate and repeatable measurements.
期刊介绍:
Ultramicroscopy is an established journal that provides a forum for the publication of original research papers, invited reviews and rapid communications. The scope of Ultramicroscopy is to describe advances in instrumentation, methods and theory related to all modes of microscopical imaging, diffraction and spectroscopy in the life and physical sciences.