Biological electron energy loss spectroscopy in the field-emission scanning transmission electron microscope.

Scanning microscopy. Supplement Pub Date : 1994-01-01

R D Leapman, S Q Sun, J A Hunt, S B Andrews

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Abstract

The dedicated scanning transmission electron microscope (STEM) combined with parallel electron energy loss spectroscopy (EELS) provides a very sensitive means of detecting specific elements in small structures. EELS is more sensitive than optimized energy-dispersive X-ray spectroscopy by a factor of about three for calcium. Measurement of such low concentrations requires special processing methods such as difference-acquisition techniques and multiple least squares procedures for fitting reference spectra. By analyzing data recorded at each pixel in a spectrum-image it is possible to map quantitatively the elemental distributions in a specimen. It is possible to prepare cryosections that are sufficiently thin to avoid excessive plural inelastic scattering so analysis can be performed at 100 keV beam energy. Under optimal conditions, a resolution of 10 nm and detection limits of a few atoms are achievable for elements such as calcium, phosphorus and iron. In the field emission STEM certain types of chemical information can be extracted from biological specimens. Valence EELS has been exploited to measure water distributions in frozen hydrated cryosections.

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场发射扫描透射电子显微镜中的生物电子能量损失谱。

专用扫描透射电子显微镜(STEM)与平行电子能量损失光谱(EELS)相结合，提供了一种非常灵敏的检测小结构中特定元素的手段。EELS比优化的能量色散x射线光谱法对钙的灵敏度高约3倍。如此低浓度的测量需要特殊的处理方法，如差分采集技术和用于拟合参考光谱的多重最小二乘程序。通过分析光谱图像中每个像素处记录的数据，可以定量地绘制样品中的元素分布。有可能制备足够薄的冷冻切片，以避免过多的复数非弹性散射，因此可以在100 keV束流能量下进行分析。在最佳条件下，对于钙、磷和铁等元素，可以实现10纳米的分辨率和少数原子的检测限。在场发射STEM中，可以从生物标本中提取某些类型的化学信息。价态EELS已被用于测量冷冻水合冷冻切片中的水分布。

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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Scanning microscopy. Supplement

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