Ground-Based Remote Sensing of CO2 in the Atmospheric Column Using a Portable Laser Heterodyne Radiometer with a Balanced Photodetector

Tingting Wei, Jingjing Wang, Fengjiao Shen, T. Tan, Z. Cao, Xiaoming Gao, P. Jeseck, Yao-Veng Te, Stéphane Plus, Lei Dong, Weidong Chen
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Abstract

Measurement of vertical concentration profiles of atmospheric trace gases is of great interest to understand the physics, chemistry, dynamics, and radiation budget of the atmosphere as well as to validate the results provided from chemical models and satellite observations. The laser heterodyne radiometer (LHR), as a passive remote sensing technique, was introduced and developed in 1970s to meet the needs of observing O3 hole in the atmosphere [1]–[3]. Since then, due to the lack of a suitable tunable laser source being used as a local oscillator (LO) for heterodyne measurement, LHR applications stayed almost in silence. Over the last decade, there has been a revival of the LHR technique as a result of significant advances in lasers and photonics technology [4]. Compared to the currently used Fourier transform spectrometer (FTS) for ground-based measurement of trace gases in the atmospheric column, the LHR offers unique advantages including high spectral resolution (<10−3 cm−1, determined by the selected electronic filter bandwidths), high sensitivity (within a factor of ~ 2 of the quantum noise limit), high spatial resolution owing to very small coherent field of view (FoV), and cost-effective compact instrumental dimension.
利用带平衡光电探测器的便携式激光外差辐射计地面遥感大气中CO2
大气痕量气体垂直浓度分布的测量对于了解大气的物理、化学、动力学和辐射收支以及验证化学模型和卫星观测提供的结果具有重要意义。激光外差辐射计(laser heterodyne radiometer, LHR)作为一种被动遥感技术,是20世纪70年代为满足观测大气O3空洞的需要而引入和发展起来的[1]-[3]。从那时起,由于缺乏合适的可调谐激光源用作外差测量的本振(LO), LHR应用几乎处于沉默状态。在过去的十年中,由于激光和光子学技术的重大进步,LHR技术得到了复兴[4]。与目前用于地面测量大气柱中痕量气体的傅立叶变换光谱仪(FTS)相比,LHR具有独特的优势,包括高光谱分辨率(<10−3 cm−1,由所选电子滤波器带宽决定),高灵敏度(在量子噪声极限的2因子内),由于非常小的相干视场(FoV)而具有高空间分辨率,并且具有成本效益紧凑的仪器尺寸。
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