无孔径红外显微镜与共聚焦红外显微镜的性能比较

Q3 Chemistry

Journal of Spectral Imaging Pub Date : 2019-04-01 DOI:10.1255/JSI.2019.A8

C. Sandt, Z. Dionnet, M. Toplak, E. Fernández, R. Brunetto, Ferenc Borondics

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引用次数: 10

摘要

我们比较了用与同步辐射源耦合的共焦显微镜与配备焦平面阵列（FPA）探测器的显微镜记录的相同样品的高光谱红外光栅图和图像的对比度、清晰度和分辨率。使用了生物样品（头发和皮肤切片）和天体物理学样品（陨石颗粒）。所提供的样品尺寸只有几微米，例如嵌入的颗粒、单个独特的细胞或薄层。我们的结果表明，FPA图像的实际空间分辨率和对比度低于共焦显微镜的光谱图。FPA显微镜也产生了缺乏准确性的测量结果：样本的大小、特征和峰值强度估计不准确。更令人惊讶的是，FPAimages中吸收峰的强度低于用共焦显微镜从相同样品测量的强度。我们的测量强调了FPA和共焦显微镜的互补性。FPA可用于快速测量样品的整体成分并检测其成分的分布，但可能无法测量小特征的确切化学组成，也可能无法检测相邻位置之间的微弱光谱差异。无孔径系统的平均效应不仅影响图像分辨率，还会降低其光谱精度。共焦显微镜天生较慢，但在衍射极限下可以更准确地测量局部成分。

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Performance comparison of aperture-less and confocal infrared microscopes

We compared hyperspectral infrared raster maps and images for contrast, definition and resolution of the same samples recorded with a confocal microscope coupled with a synchrotron radiation source vs a Focal Plane Array (FPA) detector equipped microscope. Biological samples (hair and skin sections) and astrophysics samples (meteoritic grains) were used. The samples presented are a few microns in size, such as embedded particles, a single unique cell or thin layer. Our results show that the actual spatial resolution and contrast of FPA images were lower than spectral maps from the confocal microscope. The FPA microscope also produced measurements that lacked accuracy: size of sample features and peak intensity were inaccurately estimated. More surprisingly, the intensity of absorption peaks in the FPA images was lower than the intensity measured from the same sample with a confocal microscope. Our measurements underlined the complementarity of FPA and confocal microscopes. FPA can be used to quickly measure the overall composition of a sample and detect the distribution of its components, but may fail measuring the exact chemical composition of the small features and may not detect weak spectral differences between adjacent positions. The averaging effect of aperture-less systems not only affects image resolution but also lowers their spectral accuracy. Confocal microscopes are inherently slower but give a more accurate measurement of the local composition at the diffraction limit.

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来源期刊

Journal of Spectral Imaging Chemistry-Analytical Chemistry

CiteScore

3.90

自引率

0.00%

发文量

审稿时长

22 weeks

期刊介绍： JSI—Journal of Spectral Imaging is the first journal to bring together current research from the diverse research areas of spectral, hyperspectral and chemical imaging as well as related areas such as remote sensing, chemometrics, data mining and data handling for spectral image data. We believe all those working in Spectral Imaging can benefit from the knowledge of others even in widely different fields. We welcome original research papers, letters, review articles, tutorial papers, short communications and technical notes.