Clay Minerals Mapping from Imaging Spectroscopy

G. Grandjean, X. Briottet, K. Adeline, A. Bourguignon, A. Hohmann
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引用次数: 7

Abstract

Mapping subsurface clay minerals is an important issue because they have particular behaviors in terms of mechanics and hydrology that directly affects assets laid at the surface such as buildings, houses, etc. They have a direct impact in ground stability due to their swelling capacities, constraining infiltration processes during flooding, especially when moisture is important. So detecting and characterizing clay mineral in soils serve urban planning issues and improve the risk reduction by predicting impacts of subsidence on houses and infrastruc-tures. High-resolution clay maps are thus needed with accurate indications on mineral species and abundances. Clay minerals, known as phyllosilicates, are divided in three main species: smectite, illite, and kaolinite. The smectite group highly contributes to the swelling behavior of soils, and because geotechnical soil analyses are expensive and time-consuming, it is urgent to develop new approaches for mapping clays' spatial distribution by using new technologies, e.g., ground spectrometer or remote hyperspectral cameras [0.4-2.5 μm]. These technics constitute efficient alternatives to conventional methods. We present in this chapter some recent results we got for characterizing clay species and their abundances from spectrometry, used either from a ground spectrometer or from hyperspectral cameras.
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粘土矿物成像光谱制图
地下粘土矿物的测绘是一个重要的问题,因为它们在力学和水文方面具有特殊的行为,直接影响到地表的资产,如建筑物、房屋等。由于它们的膨胀能力,它们对地面稳定性有直接的影响,在洪水期间限制渗透过程,特别是当水分很重要时。因此,检测和表征土壤中的粘土矿物有助于城市规划问题,并通过预测下沉对房屋和基础设施的影响来降低风险。因此,需要高分辨率的粘土图,以准确指示矿物种类和丰度。粘土矿物被称为层状硅酸盐,分为三大类:蒙脱石、伊利石和高岭石。蒙脱石组对土壤的膨胀行为有很大的影响,由于岩土分析成本高且耗时长,因此迫切需要利用新技术,如地面光谱仪或远程高光谱相机[0.4-2.5 μm],开发新的方法来绘制粘土的空间分布。这些技术是传统方法的有效替代品。在本章中,我们介绍了我们最近从光谱法中获得的粘土种类及其丰度特征的一些结果,这些结果要么来自地面光谱仪,要么来自高光谱相机。
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