快速和通用的环境表面分析等离子体辅助解吸/电离质谱

Q4 Chemistry Spectroscopy Europe Pub Date : 2015-12-08 DOI:10.1255/sew.2015.a2
F. Rutten, J. Jamur, P. Roach
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引用次数: 2

摘要

表面在广泛的应用中起着至关重要的作用,因此自化学分析的早期以来一直是深入研究的主题。随着知识和制造能力的增加,对更详细的表面分析信息的需求在过去几年中迅速增长。虽然振动光谱,特别是,已经在广泛的设置中产生了重要的信息,但这些技术的本质确实限制了信息的可用性。另一方面,质谱法有能力产生非常详细的数据集,但传统上在实际应用中明显不方便。在最初的使用之后,主要用于无机和材料科学应用,以及Alfred Benninghoven(德国)和David Briggs(英国)是主要的主角,液态金属离子枪和时间飞行分析仪的进步使二次离子质谱(SIMS)成为分析有机材料的强大技术。在上个世纪后半叶,灵敏度的逐步变化彻底改变了SIMS的使用,使研究人员能够在不显着改变所研究的表面化学的情况下,从易损坏的有机材料中获得详细的质谱。此外,包含大分子信息的表面质谱可以从非常小的表面积生成,特别是自从引入簇一次离子源以来,允许以每个图像像素的高质量范围和高分辨率光谱的形式生成具有大量信息的微米尺度图像。这些发展开辟了分析和飞行时间模拟(ToF-SIMS)的全新领域,从医学植入物和细胞生物学到天体化学,艺术史和考古学,在看似无穷无尽的应用范围内得到了非常成功的应用虽然许多精致的研究已经并将继续使用SIMS发表,但一个关键的限制是要求样品处于真空环境中。这就需要对真空敏感的样品进行特别制备,以消除任何不利影响。此外,样品吞吐量受泵降时间和样品大小和几何形状的限制
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Fast and versatile ambient surface analysis by plasma-assisted desorption/ionisation mass spectrometry
Introduction Surfaces play a crucial role in a wide range of applications, hence have been the subject of intense study since the very early days of chemical analysis. With increasing knowledge and manufacturing capabilities, the need for ever more detailed surface analytical information has grown rapidly over the years. Whilst vibrational spectroscopies, in particular, have yielded crucial information in a wide range of settings, the very nature of these techniques does limit the information available. Mass spectrometry on the other hand has the capability to yield exquisitely detailed datasets, but has traditionally been significantly less convenient in actual applications. After initial use, predominantly for inorganic and materials science applications and with Alfred Benninghoven (Germany) and David Briggs (UK) among the main protagonists, advances in liquid metal ion guns and time-offlight analysers enabled secondary ion mass spectrometry (SIMS) to become a powerful technique for the analysis of organic materials. A step-change in sensitivity revolutionised the use of SIMS in the latter part of the last century and allowed researchers to acquire detailed mass spectra from damageprone organic materials without significantly altering the surface chemistry under investigation. Moreover, surface mass spectra containing information on large molecules can be generated from very small surface areas, especially since the introduction of cluster primary ion sources, allowing micron-scale image generation with an enormous wealth of information, in the form of a high mass-range and -resolution spectrum for each image pixel. These developments opened up entire new fields of analysis and time-of-flight SIMS (ToF-SIMS) has since been applied highly successfully in a seemingly endless range of applications from medical implants and cell biology to astrochemistry, art history and archaeology.1 Whilst much exquisite research has been and continues to be published using SIMS, a crucial restriction is the requirement for samples to be in a vacuum environment. This necessitates samples sensitive to vacuum to be especially prepared to negate any adverse effects. Moreover, sample throughput is restricted by pump-down times and sample size and geometry are limited to
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来源期刊
Spectroscopy Europe
Spectroscopy Europe Chemistry-Analytical Chemistry
CiteScore
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期刊介绍: Spectroscopy Europe is the only European publication dedicated to all areas of Spectroscopy. It publishes a wide range of articles on the latest developments, interesting and important applications, new techniques and the latest development in the field. This controlled-circulation magazine is available free-of-charge to qualifying individuals engaged in spectroscopy within Europe. Includes regular news, a comprehensive diary of events worldwide, product introductions, meeting reports, book reviews and regular columns on chemometrics, data handling, process spectroscopy and reference materials.
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