Combined Pulsed RF GD-OES and HAXPES for Quantified Depth Profiling through Coatings

M. Bouttemy, S. Béchu, B. Spencer, Pia Dally, P. Chapon, A. Etcheberry
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引用次数: 5

Abstract

Chemical characterization at buried interfaces is a real challenge, as the physico-chemical processes operating at the interface govern the properties of many systems and devices. We have developed a methodology based on the combined use of pulsed RF GD-OES (pulsed Radio Frequency Glow Discharge Optical Emission Spectrometry) and XPS (X-ray Photoelectron Spectroscopy) to facilitate the access to deeply buried locations (taking advantage of the high profiling rate of the GD-OES) and perform an accurate chemical diagnosis using XPS directly inside the GD crater. The reliability of the chemical information is, however, influenced by a perturbed layer present at the surface of the crater, hindering traditional XPS examination due to a relatively short sampling depth. Sampling below the perturbed layer may, however, can be achieved using a higher energy excitation source with an increased sampling depth, and is enabled here by a new laboratory-based HAXPES (Hard X-ray PhotoElectron Spectroscopy) (Ga-Kα, 9.25 keV). This new approach combining HAXPES with pulsed RF GD-OES requires benchmarking and is here demonstrated and evaluated on InP. The perturbed depth is estimated and the consistency of the chemical information measured is demonstrated, offering a new route for advanced chemical depth profiling through coatings and heterostructures.
结合脉冲射频GD-OES和HAXPES的涂层深度定量分析
埋藏界面的化学表征是一个真正的挑战,因为在界面上运行的物理化学过程控制着许多系统和设备的性质。我们开发了一种基于脉冲RF GD- oes(脉冲射频辉光发射光谱法)和XPS (x射线光电子能谱法)结合使用的方法,以方便进入深埋位置(利用GD- oes的高剖面率),并使用XPS直接在GD陨石坑内进行准确的化学诊断。然而,化学信息的可靠性受到陨石坑表面存在的扰动层的影响,由于采样深度相对较短,阻碍了传统的XPS检查。然而,在扰动层下的采样可以使用更高能量的激发源和增加的采样深度来实现,并且可以通过新的实验室HAXPES(硬x射线光电子能谱)(Ga-Kα, 9.25 keV)来实现。这种将HAXPES与脉冲RF GD-OES相结合的新方法需要基准测试,并在InP上进行了演示和评估。估计了扰动深度,并证明了测量的化学信息的一致性,为通过涂层和异质结构进行先进的化学深度剖面分析提供了新的途径。
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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