An Underwater Methane Sensor Based on Laser Spectroscopy in a Hollow Core Optical Fiber

IF 8.2 1区化学 Q1 CHEMISTRY, ANALYTICAL ACS Sensors Pub Date : 2024-11-10 DOI:10.1021/acssensors.4c01563

Jason A. Kapit, Sarah Youngs, William A. Pardis, Alexandra M. Padilla, Anna P. M. Michel

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Abstract

Existing sensors for measuring dissolved methane in situ suffer from excessively slow response times or large size and complexity. The technology reported here realizes improvements by utilizing a hollow core optical fiber (HFC) as the detection cell in an underwater infrared laser spectrometer. The sensor operates by using a polymer membrane inlet to continuously extract dissolved gas from water. Once inside the sensor, the gas passes through an HCF, within which tunable diode laser spectroscopy is used to quantify methane. The use of an HCF for the optical cell enables advantages of sensitivity, selectivity, compactness, response time, and ease of integration. A submersible prototype has been developed, characterized in the laboratory, and tested in the ocean to a depth of 2000 m. Initial laboratory environmental testing showed a pCH₄ detection range up to 10,000 μatm, an uncertainty of 5.6 μatm or ±1.4% (whichever is greater) and a response time of 4.6 min over a range of controlled operating conditions. Operation at sea demonstrated its utility in generating dissolved methane maps, targeted point sampling, and water column profiling.

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基于中空芯光纤激光光谱学的水下甲烷传感器

现有的现场测量溶解甲烷的传感器存在响应速度过慢、体积庞大和结构复杂等问题。本文报告的技术通过利用中空芯光纤（HFC）作为水下红外激光光谱仪的检测单元实现了改进。传感器的工作原理是利用聚合物膜进气口不断从水中提取溶解气体。进入传感器后，气体通过 HCF，在 HCF 中使用可调谐二极管激光光谱仪对甲烷进行量化。使用 HCF 作为光学单元具有灵敏度高、选择性强、结构紧凑、响应时间短和易于集成等优点。最初的实验室环境测试表明，pCH4 的检测范围可达 10,000 μatm，不确定性为 5.6 μatm 或 ±1.4%（以较大者为准），在一系列受控操作条件下的响应时间为 4.6 分钟。在海上的运行证明了其在生成溶解甲烷图、目标点取样和水柱剖面测量方面的实用性。

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来源期刊

ACS Sensors Chemical Engineering-Bioengineering

CiteScore

14.50

自引率

3.40%

发文量

372

期刊介绍： ACS Sensors is a peer-reviewed research journal that focuses on the dissemination of new and original knowledge in the field of sensor science, particularly those that selectively sense chemical or biological species or processes. The journal covers a broad range of topics, including but not limited to biosensors, chemical sensors, gas sensors, intracellular sensors, single molecule sensors, cell chips, and microfluidic devices. It aims to publish articles that address conceptual advances in sensing technology applicable to various types of analytes or application papers that report on the use of existing sensing concepts in new ways or for new analytes.