High precision detection method of methane in extreme environment based on TDLAS

International Symposium on Advanced Optical Manufacturing and Testing Technologies (AOMATT) Pub Date : 2021-12-13 DOI:10.1117/12.2604823

Tingting Zhang, Lin Zhang, Yanfang Li, Yubin Wei, Zhaowei Wang, Weihua Gong, Lei Lv, Jiqiang Wang, Tong-yu Liu

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引用次数: 1

Abstract

ABSTRACT The continuous emission of greenhouse gases leads to the sharp rise of environmental temperature. Its content and distribution also affect the atmosphere radiation, climate characteristics, stratosphere troposphere exchange (STE) and circulation in the near-tropopause region. Methane is the second most important greenhouse gas after carbon dioxide, and its concentration has strong gradients near the tropopause. Therefore, the sensitivity, accuracy of methane detection approach in extreme environment have been greatly restricted, and this has become a technical bottleneck for low-temperature and low-pressure gas detection. To address this, a novel 3-dimensional compensation model of temperature and pressure is reported based on the simulation of methane absorption characteristic. Through a detailed investigation, the simulation system and compensation model are evaluated, the detection accuracy is improved by an order of magnitude; the minimum detection limit is ~0.012ppm with integration time is 59s.

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基于TDLAS的极端环境甲烷高精度检测方法

温室气体的持续排放导致环境温度急剧上升。它的含量和分布也影响大气辐射、气候特征、平流层对流层交换和近对流层顶区域的环流。甲烷是仅次于二氧化碳的第二大温室气体，其浓度在对流层顶附近有很强的梯度。因此，极端环境下甲烷检测方法的灵敏度、准确性受到很大限制，成为低温低压气体检测的技术瓶颈。为了解决这一问题，在模拟甲烷吸收特性的基础上，提出了一种新的三维温度和压力补偿模型。通过详细的研究，对仿真系统和补偿模型进行了评价，检测精度提高了一个数量级;最小检出限为~0.012ppm，积分时间为59s。

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International Symposium on Advanced Optical Manufacturing and Testing Technologies (AOMATT)

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