由低频弹弓形石英音叉和光学增强实现的超灵敏CH4-LITES传感器。

IF 9.1 1区化学 Q1 CHEMISTRY, ANALYTICAL

ACS Sensors Pub Date : 2025-10-07 DOI:10.1021/acssensors.5c02573

Hanxu Ma,Shaoning Zheng,Runqiu Wang,Ying He,Yanjun Chen,Xiaorong Sun,Shunda Qiao,Yufei Ma

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引用次数: 0

摘要

本文首次报道了基于低频弹弓形石英音叉（QTF）和光学增强的超灵敏甲烷(CH4)-LITES传感器。弹弓形QTF作为核心创新元件，具有低谐振频率（~ 7.9 kHz）、宽叉隙（>1000 μm）和弹弓形弯曲过渡结构，显著延长了声能积累时间，抑制了光散射噪声，优化了应力分布，从而全面提高了传感器性能。有限元模拟结果表明，与标准商用QTF相比，弹弓型QTF的最大温度梯度和总表面电荷分别增加了3.53和2.68倍。实验验证表明，基于弹弓形状QTF的LITES系统的信噪比（SNR）比使用标准QTF的LITES系统提高了2.26倍。为了进一步优化CH4的检测性能，采用拉曼光纤放大器（RFA）增强二极管激光器的功率，采用密集光斑图光程长度约为80 m的多通电池（MPC）和自行设计的放大器分别促进气体吸收和提高信号增益。这三个组成部分协同工作，通过增加激发强度、促进气体吸收和提高信号增益来有效提高传感器的检测能力。在该配置下，传感器对CH4的最小检测限（MDL）为8.42 ppb，噪声等效归一化吸收系数（NNEA）为1.38 × 10-9 cm-1·W·Hz-1/2。Allan偏差分析表明，在平均350秒的时间内，传感器的MDL优化到0.72 ppb。本研究为高灵敏度CH4气体检测提供了一种具有显著性能优势的新型QTF结构和光学增强策略，在环境监测和工业安全等领域具有重要的应用前景。

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Ultra-Sensitive CH4-LITES Sensor Enabled by Low-Frequency Slingshot-Shaped Quartz Tuning Fork and Optical Enhancement.

This paper reports for the first time an ultrasensitive methane (CH4)-LITES sensor based on a low-frequency slingshot-shaped quartz tuning fork (QTF) and optical enhancement. The slingshot-shaped QTF serves as the core innovative component, featuring low resonant frequency (∼7.9 kHz), wide prong gap (>1000 μm), and slingshot-shaped curved transition structure, which significantly extends acoustic energy accumulation time, suppresses optical scattering noise, and optimizes stress distribution, thereby comprehensively enhancing sensing performance. Finite element simulation results demonstrate that, compared to a standard commercial QTF, the maximum temperature gradient and total surface charge of the slingshot-shaped QTF increased by factors of 3.53 and 2.68, respectively. Experimental validation shows that the signal-to-noise ratio (SNR) of the LITES system based on this slingshot-shaped QTF improved by 2.26 times compared to the system using a standard QTF. To further optimize the detection performance for CH4, a Raman fiber amplifier (RFA) was employed to enhance the power of the diode laser, while a multipass cell (MPC) with a dense spot pattern and an optical path length of approximately 80 m, along with a self-designed amplifier, were used to promote gas absorption and enhance signal gain, respectively. These three components work synergistically to effectively improve the sensor's detection capability by increasing excitation intensity, promoting gas absorption, and enhancing signal gain. In this configuration, the sensor's minimum detection limit (MDL) for CH4 was calculated to be 8.42 ppb, and the noise-equivalent normalized absorption coefficient (NNEA) was calculated as 1.38 × 10-9 cm-1·W·Hz-1/2. Allan deviation analysis indicated that at an averaging time of 350 s, the sensor's MDL was optimized to 0.72 ppb. This study provides a novel QTF structure with significant performance advantages and an optical enhancement strategy for highly sensitive CH4 gas detection, holding important application prospects in fields such as environmental monitoring and industrial safety.

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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.