Preliminary Results of Microwave Induced Thermoacoustics Imaging in Geological Media

Chang Liu, Xu Mao, Juan Heredia Juesas, A. Molaei, J. Martinez-Lorenzo
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引用次数: 3

Abstract

Seismic and electromagnetic imaging modalities are conventionally used in subsurface situational awareness applications. These modalities have been very effective at characterizing the geological media in terms of its constitutive mechanical properties such as density and compressibility, as well as electromagnetic properties such as electric conductivity, permeability, and permittivity. In order to enhance these imaging capabilities, a Thermoacoustic (TA) imaging system is used in this work. TA imaging relies on the coupling of mechanical and electromagnetic waves through a thermodynamic process, and it has the potential to reconstruct thermodynamic constitutive properties such as volumetric expansion coefficient and heat capacity. TA imaging has been mostly used in biological applications; this is due to the low signal-to-noise ratio that can be created with this physical mechanism. This work is aimed at addressing such limitation and exploring the use of TA imaging in geophysical applications. Conventionally, a short microwave pulse excitation is used to create the TA wave; so that the stress confinement condition is met while providing high resolution images. This approach requires the use of expensive high power amplifiers to create a detectable TA signal. This limitation can be addressed by using a frequency-modulated continuous wave (FMCW) excitation, which has been recently proposed as a suitable mechanism to enhance the signal-to-noise ratio of the TA signal generated for a given peak power constrain. This paper discusses and compares both pulsed and FMCW TA imaging in geological media. Preliminary experimental results show the efficacy of this approach to image a rock immersed in an oil bath; thus paving the way towards its future use for subsurface sensing and imaging of fluid flow and transport in porous media.
地质介质中微波热声成像的初步结果
地震和电磁成像模式通常用于地下态势感知应用。这些模式在描述地质介质的本构力学特性(如密度和压缩性)以及电磁特性(如导电性、渗透率和介电常数)方面非常有效。为了提高这些成像能力,在这项工作中使用了热声(TA)成像系统。TA成像通过热力学过程依赖于机械波和电磁波的耦合,它有可能重建热力学本构性质,如体积膨胀系数和热容量。TA成像主要用于生物领域;这是由于这种物理机制可以产生低信噪比。这项工作旨在解决这些限制,并探索在地球物理应用中使用TA成像。传统上,使用短微波脉冲激发来产生TA波;从而在提供高分辨率图像的同时满足应力约束条件。这种方法需要使用昂贵的高功率放大器来产生可检测的TA信号。这一限制可以通过使用调频连续波(FMCW)激励来解决,这是最近提出的一种合适的机制,可以提高给定峰值功率约束下产生的TA信号的信噪比。本文讨论并比较了地质介质中的脉冲TA成像和FMCW TA成像。初步实验结果表明,该方法对浸在油浴中的岩石成像是有效的;从而为其未来用于多孔介质中流体流动和输送的地下传感和成像铺平了道路。
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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