Litcius/Paper detail

Dual-frequency modulation quartz crystal tuning fork–enhanced laser spectroscopy

Linguang Xu, Ningwu Liu, Sheng Zhou, Lei Zhang, Benli Yu, Horst Fischer, Jingsong Li

2020Optics Express28 citationsDOIOpen Access PDF

Abstract

An innovative trace gas-sensing technique utilizing a single quartz crystal tuning fork (QCTF) based on a photoelectric detector and dual-frequency modulation technique was demonstrated for the first time for simultaneous multi-species detection. Instead of traditional semiconductor detectors and lock-in amplifier, we utilized the piezoelectric effect and resonant effect of the QCTF to measure the light intensity. A fast signal analysis method based on fast Fourier transform (FFT) algorithm is proposed for overlapping signal extraction. To explore the capabilities of this technique, a gas-sensing system based on two lasers having center emission wavelength of 1.653 µm (a DFB laser diode in the near-IR) and 7.66 µm (an EC QCL in the mid-IR) is successfully demonstrated for simultaneous CH 4 spectroscopy measurements. The results indicate a normalized noise equivalent absorption (NNEA) coefficients of 1.33×10 −9 cm −1 W·Hz −1/2 at 1.653 µm and 2.20×10 −10 cm −1 W·Hz −1/2 at 7.66 µm, were achieved. This proposed sensor architecture has the advantages of easier optical alignment, lower cost, and a compactness compared to the design of a conventional TDLAS sensor using multiple semiconductor detectors for laser signal collection. The proposed technique can also be expanded to common QEPAS technique with multi-frequency modulation for multiple species detection simultaneously.

Topics & Concepts

OpticsMaterials scienceSpectroscopyModulation (music)Crystal (programming language)LaserPhase modulationQuartzOptoelectronicsPhase noisePhysicsComputer scienceQuantum mechanicsComposite materialProgramming languageAcousticsSpectroscopy and Laser ApplicationsAcoustic Wave Resonator TechnologiesTerahertz technology and applications