用X射线光电子能谱分析钠钙硅玻璃近表面的结构特征

IF 2.1 3区 材料科学 Q2 MATERIALS SCIENCE, CERAMICS International Journal of Applied Glass Science Pub Date : 2022-08-15 DOI:10.1111/ijag.16604
Barsheek Roy, Felix Baier, Andreas Rosin, Thorsten Gerdes, Stefan Schafföner
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引用次数: 0

摘要

利用x射线光电子能谱(XPS)描述了钠-石灰-二氧化硅(SLS)玻璃近表面区域的结构化学。通过连续的XPS测量和Ar+溅射对O1s和Si2p光谱线进行了深入的研究,揭示了桥氧、非桥氧(NBO)和含水物质(SiOH/H2O)的浓度随距离玻璃表面的深度而变化。在O1s轨道曲线拟合光谱中考虑上述每种氧形态的情况下,计算出Ototal/Si原子比在整个溅射深度(总持续时间为110 min)范围内变化在2.90-3.74之间。深度为1-3 nm的玻璃表面Ototal/Si比最高,为3.74,代表了Q0和Q1物质的机械弱结构,标志着每个硅四面体单元分别连接了4个和3个NBOs。这表明了与硅烷醇基团相关的水合物质对SLS玻璃近表面结构的重要贡献。
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Structural characterization of the near-surface region of soda–lime–silica glass by X-ray photoelectron spectroscopy

The structural chemistry of the near-surface region of soda–lime–silica (SLS) glass is described in terms of silicate network connectivity using X-ray photoelectron spectroscopy (XPS). A thorough investigation of O1s and Si2p spectral lines by sequential XPS measurements, accompanied by Ar+ sputtering, revealed the variation of concentration of bridging oxygen, non-bridging oxygen (NBO), and hydrous species (SiOH/H2O) as a function of depth from the glass surface. The Ototal/Si atomic ratio was calculated to vary in the range of 2.90–3.74 throughout the depth of sputtering for a total duration of 110 min, while considering each of the aforementioned oxygen speciations in the curve-fitted spectra of O1s orbital. The glass surface up to a depth of 1–3 nm had the highest Ototal/Si ratio of 3.74, which was representative for a mechanically weak structure with Q0 and Q1 species, marked by the respective linkages of four and three NBOs per silica tetrahedral unit. This dictates the vital contribution of the hydrous species associated with silanol groups to the near-surface structure of SLS glass.

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来源期刊
International Journal of Applied Glass Science
International Journal of Applied Glass Science MATERIALS SCIENCE, CERAMICS-
CiteScore
4.50
自引率
9.50%
发文量
73
审稿时长
>12 weeks
期刊介绍: The International Journal of Applied Glass Science (IJAGS) endeavors to be an indispensable source of information dealing with the application of glass science and engineering across the entire materials spectrum. Through the solicitation, editing, and publishing of cutting-edge peer-reviewed papers, IJAGS will be a highly respected and enduring chronicle of major advances in applied glass science throughout this century. It will be of critical value to the work of scientists, engineers, educators, students, and organizations involved in the research, manufacture and utilization of the material glass. Guided by an International Advisory Board, IJAGS will focus on topical issue themes that broadly encompass the advanced description, application, modeling, manufacture, and experimental investigation of glass.
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