fifisims:用于分析双束聚焦离子束仪器的二次离子质谱分析综述

IF 4.5 2区 材料科学 Q1 CRYSTALLOGRAPHY
Lex Pillatsch , Fredrik Östlund , Johann Michler
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引用次数: 34

摘要

次级离子质谱(SIMS)是一种众所周知的纳米级三维化学制图技术,其检测灵敏度在ppm甚至ppb范围内。能量色散x射线光谱学(EDS)是现代扫描电子显微镜(SEM)及其相关的双束聚焦离子束(FIBSEM)仪器中标准的化学分析和成像技术。与电子束的使用相反,过去离子束在fibsem中主要用于局部铣削或沉积材料。在这里,我们回顾了新兴的fifisims技术,它利用聚焦离子束作为分析探针,提供了在fifisem仪器上进行二次离子质谱测量的能力:由FIB溅射的二次离子被收集并根据它们的质量由质谱仪选择。通过这种方式,可以实现高横向分辨率< 50 nm和深度分辨率< 10 nm的完整3D化学分析。我们首先报告了SIMS和FIB技术的历史发展,并回顾了这两种仪器的最新发展。然后,我们用蒙特卡罗模拟回顾了入射粒子相互作用的物理学。其次,详细介绍了现代fifisims仪器的组成,从FIB柱中液态金属源的一次离子产生,聚焦光学,溅射离子提取光学,到不同类型的质谱仪。重点讨论了并联和串联质量选择在数据采集和解释方面的优缺点,并讨论了FIBSEM中的压力、加速电压、离子起飞角和电荷补偿技术对分析结果的影响。综述了fifisims在灵敏度、横向分辨率、深度分辨率和质量分辨率方面的能力。讨论了与停留时间、分束和光束控制策略以及粗糙度和边缘效应相关的不同数据采集策略。概述了基于同位素比和分子片段的质量鉴定数据分析程序。然后介绍了薄膜、多晶金属、电池、文化遗产材料、同位素标记和地质材料等领域的应用实例。最后,将fifisims与EDS进行了比较,并讨论了该技术与其他基于fifisem的成像技术的相关显微镜技术的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
FIBSIMS: A review of secondary ion mass spectrometry for analytical dual beam focussed ion beam instruments

Secondary ion mass spectrometry (SIMS) is a well-known technique for 3D chemical mapping at the nanoscale, with detection sensitivity in the range of ppm or even ppb. Energy dispersive X-ray spectroscopy (EDS) is the standard chemical analysis and imaging technique in modern scanning electron microscopes (SEM), and related dual-beam focussed ion beam (FIBSEM) instruments. Contrary to the use of an electron beam, in the past the ion beam in FIBSEMs has predominantly been used for local milling or deposition of material. Here, we review the emerging FIBSIMS technique which exploits the focused ion beam as an analytical probe, providing the capability to perform secondary ion mass spectrometry measurements on FIBSEM instruments: secondary ions, sputtered by the FIB, are collected and selected according to their mass by a mass spectrometer. In this way a complete 3D chemical analysis with high lateral resolution < 50 nm and a depth resolution < 10 nm is attainable.

We first report on the historical developments of both SIMS and FIB techniques and review recent developments in both instruments. We then review the physics of interaction for incident particles using Monte Carlo simulations. Next, the components of modern FIBSIMS instruments, from the primary ion generation in the liquid metal source in the FIB column, the focussing optics, the sputtered ion extraction optics, to the different mass spectrometer types are all detailed. The advantages and disadvantages of parallel and serial mass selection in terms of data acquisition and interpretation are highlighted, while the effects of pressure in the FIBSEM, acceleration voltage, ion take-off angles and charge compensation techniques on the analysis results are then discussed. The capabilities of FIBSIMS in terms of sensitivity, lateral and depth resolution and mass resolution are reviewed. Different data acquisition strategies related to dwell time, binning and beam control strategies as well as roughness and edge effects are discussed. Data analysis routines for mass identification based on isotope ratios and molecular fragments are outlined. Application examples are then presented for the fields of thin films, polycrystalline metals, batteries, cultural heritage materials, isotope labelling, and geological materials. Finally, FIBSIMS is compared to EDS, and the potential of the technique for correlative microscopy with other FIBSEM based imaging techniques is discussed.

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来源期刊
Progress in Crystal Growth and Characterization of Materials
Progress in Crystal Growth and Characterization of Materials 工程技术-材料科学:表征与测试
CiteScore
8.80
自引率
2.00%
发文量
10
审稿时长
1 day
期刊介绍: Materials especially crystalline materials provide the foundation of our modern technologically driven world. The domination of materials is achieved through detailed scientific research. Advances in the techniques of growing and assessing ever more perfect crystals of a wide range of materials lie at the roots of much of today''s advanced technology. The evolution and development of crystalline materials involves research by dedicated scientists in academia as well as industry involving a broad field of disciplines including biology, chemistry, physics, material sciences and engineering. Crucially important applications in information technology, photonics, energy storage and harvesting, environmental protection, medicine and food production require a deep understanding of and control of crystal growth. This can involve suitable growth methods and material characterization from the bulk down to the nano-scale.
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