Photothermal Spectroscopy for Planetary Sciences: Mid-IR Absorption Made Easy

arXiv - PHYS - Instrumentation and Methods for Astrophysics Pub Date : 2024-09-18 DOI:arxiv-2409.11626

Christopher Cox, Jakob Haynes, Christopher Duffey, Christopher Bennett, Julie Brisset

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Abstract

The understanding of the formation and evolution of the solar system still has many unanswered questions. Formation of solids in the solar system, mineral and organic mixing, and planetary body creation are all topics of interest to the community. Studying these phenomena is often performed through observations, remote sensing, and in-situ analysis, but there are limitations to the methods. Limitations such as IR diffraction limits, spatial resolution issues, and spectral resolution issues can prevent detection of organics, detection and identification of cellular structures, and the disentangling of granular mixtures. Optical-PhotoThermal InfraRed (O-PTIR) spectroscopy is a relatively new method of spectroscopy currently used in fields other than planetary sciences. O-PTIR is a non-destructive, highly repeatable, and fast form of measurement capable of reducing these limitations. Using a dual laser system with an IR source tuned to the mid-IR wavelength we performed laboratory O-PTIR measurements to compare O-PTIR data to existing IR absorption data and laboratory FTIR measurements for planetary materials. We do this for the purpose of introducing O-PTIR to the planetary science community. The technique featured here would serve to better measurements of planetary bodies during in-situ analysis. We find that, unlike other fields where O-PTIR produces almost one-to-one measurements with IR absorption measurements of the same material, granular materials relevant to planetary science do not. However, we do find that the materials compared were significantly close and O-PTIR was still capable of identifying materials relevant to planetary science.

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行星科学的光热光谱学：中红外吸收轻松搞定

人们对太阳系的形成和演化仍有许多未解之谜。太阳系中固体的形成、矿物和有机物的混合以及行星体的产生都是人们感兴趣的话题。对这些现象的研究通常通过观测、遥感和现场分析来进行，但这些方法都有局限性。红外衍射极限、空间分辨率问题和光谱分辨率问题等限制因素会妨碍有机物的探测、细胞结构的探测和识别以及颗粒混合物的分离。光学-光热红外（O-PTIR）光谱学是一种全新的光谱学方法，目前用于行星科学以外的领域。O-PTIR 是一种非破坏性、高重复性和快速的测量方法，能够减少这些限制。我们使用双激光系统和调谐到中红外波长的红外光源，进行了实验室 O-PTIR 测量，将 O-PTIR 数据与现有的红外吸收数据和行星材料的实验室傅立叶变换红外测量进行比较。我们这样做的目的是向行星科学界介绍 O-PTIR 技术。这里介绍的技术将有助于在原位分析过程中更好地测量行星体。我们发现，在其他领域，O-PTIR 与同种材料的红外吸收测量结果几乎是一一对应的，而与行星科学相关的颗粒材料则不同。不过，我们发现所比较的材料非常接近，而且 O-PTIR 仍然能够识别与行星科学有关的材料。

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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arXiv - PHYS - Instrumentation and Methods for Astrophysics

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