Effective Attenuation Lengths for Different Quantitative Applications of X-ray Photoelectron Spectroscopy

IF 4.4 2区 工程技术 Q2 CHEMISTRY, MULTIDISCIPLINARY Journal of Physical and Chemical Reference Data Pub Date : 2020-07-13 DOI:10.1063/5.0008576
A. Jablonski, C. Powell
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引用次数: 23

Abstract

The effective attenuation length (EAL) is a useful parameter in quantitative applications of x-ray photoelectron spectroscopy (XPS). This parameter is used in place of the inelastic mean free path (IMFP) in expressions for different XPS applications to correct those expressions for elastic scattering of the photoelectrons. We consider expressions used to determine (i) the thickness of an overlayer film on a planar substrate, (ii) the surface composition, (iii) the depth of a thin marker or delta layer, and (iv) the shell thickness of a core–shell nanoparticle. An EAL can be used for each of these applications. In general, the EAL depends on the particular defining equation as well as on the XPS configuration. Many attempts were made in the 1970s and 1980s to measure EALs for the determination of overlayer-film thicknesses, but there were often wide scatters in the reported results due to the difficulty in preparing uniform films with known thicknesses. We have therefore been motivated to calculate EALs for each application. The SRD 82 database from the National Institute of Standards and Technology (NIST) provides EALs for the measurement of overlayer-film thicknesses and of marker-layer depths. These EALs can be determined for photoelectron energies between 50 eV and 2 keV and for user-specified XPS configurations. We review EAL predictive equations for the determination of overlayer-film thicknesses on a planar substrate for XPS with unpolarized x rays and with linearly polarized x rays as well as an EAL predictive equation for quantitative analysis by XPS. These equations are simple analytical expressions that are valid for well-defined ranges of experimental conditions and for useful ranges of electron energies. We also point out that EALs for the determination of overlayer-film thicknesses can be derived from the simulated photoelectron intensities obtained from the NIST Database for the Simulation of Electron Spectra for Surface Analysis (SRD 100). Where possible, we make comparisons of the calculated EALs with illustrative experimental results. A key parameter in the EAL predictive equations is the so-called albedo, a useful measure of the strength of elastic-scattering effects in a material. The albedo is a simple function of the IMFP and the transport mean free path (TRMFP). We provide a tabulation of albedo and TRMFP values in the supplementary material for 41 elemental solids and 42 inorganic compounds for photoelectron energies between 50 eV and 30 keV. For other materials, albedo values can be determined from IMFP and TRMFP data available in the NIST SRD 82 and SRD 100 databases.
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x射线光电子能谱不同定量应用的有效衰减长度
有效衰减长度(EAL)是x射线光电子能谱(XPS)定量应用中的一个有用参数。在不同XPS应用的表达式中使用该参数代替非弹性平均自由程(IMFP),以校正光电子的弹性散射的那些表达式。我们考虑用于确定(i)平面基底上覆盖层膜的厚度,(ii)表面组成,(iii)薄标记物或德尔塔层的深度,以及(iv)核-壳纳米颗粒的壳厚度的表达式。EAL可以用于这些应用程序中的每一个。通常,EAL取决于特定的定义方程以及XPS配置。在20世纪70年代和80年代,人们进行了许多尝试来测量EAL以确定覆盖层膜的厚度,但由于难以制备具有已知厚度的均匀膜,在所报道的结果中通常存在广泛的散射。因此,我们有动力为每个应用程序计算EAL。美国国家标准与技术研究所(NIST)的SRD 82数据库提供了用于测量覆盖层膜厚度和标记层深度的EAL。这些EAL可以针对50eV和2keV之间的光电子能以及针对用户指定的XPS配置来确定。我们综述了用非偏振x射线和线性偏振x射线测定平面衬底上XPS覆盖层膜厚度的EAL预测方程,以及用XPS定量分析的EAL预报方程。这些方程是简单的分析表达式,适用于定义明确的实验条件范围和电子能量的有用范围。我们还指出,用于确定覆盖层膜厚度的EAL可以从NIST表面分析电子光谱模拟数据库(SRD 100)中获得的模拟光电子强度中导出。在可能的情况下,我们将计算的EAL与说明性实验结果进行比较。EAL预测方程中的一个关键参数是所谓的反照率,这是衡量材料中弹性散射效应强度的有用指标。反照率是IMFP和传输平均自由程(TRMFP)的简单函数。我们提供了补充材料中41种元素固体和42种无机化合物的反照率和TRMFP值的表格,光电子能在50eV和30keV之间。对于其他材料,反照率值可以从NIST SRD 82和SRD 100数据库中可用的IMFP和TRMFP数据中确定。
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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来源期刊
CiteScore
6.90
自引率
11.60%
发文量
14
审稿时长
>12 weeks
期刊介绍: The Journal of Physical and Chemical Reference Data (JPCRD) is published by AIP Publishing for the U.S. Department of Commerce National Institute of Standards and Technology (NIST). The journal provides critically evaluated physical and chemical property data, fully documented as to the original sources and the criteria used for evaluation, preferably with uncertainty analysis. Critical reviews may also be included if they document a reference database, review the data situation in a field, review reference-quality measurement techniques, or review data evaluation methods.
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