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Microfiber evanescent-field photothermal gas detection using acoustic-induced mode-dependent frequency shift

Zhu Yi et al · Wiley · 2023

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In this study, we experimentally showcase the microfiber evanescent-field photothermal gas detection by exploiting all-fiber MHz-level frequency shift scheme. Based on the acousto-optic interaction effect, the low-frequency shifts of 0.9 MHz and 1.83 MHz can be obtained through the cyclic conversion between the transverse core modes LP01 and LP11 in the few-mode fiber. Our proposed all-fiber frequency shifters show flexible MHz-level up(down) frequency shifts with superior sideband rejection ratio (over 40 dB) and low insertion loss (less than 1 dB). Furthermore, an all-fiber heterodyne interferometric detection system is implemented by leveraging the above low-frequency shifters, in which around 1-μm-diameter microfiber is investigated for photothermal gas detection. A pump-probe configuration is employed to obtain the photothermal effect induced by the gas absorption of the modulated evanescent field. By demodulating the phase of the beat signal output by the interferometer, an equivalent detection limit (1σ) of 32 ppm and a response time of 22 s are achieved for ammonia, as well as 0.24 % instability within 48 pump cycles. Given its compact all-fiber configuration and high sensitivity with fast response, the experimental results can pave the way for widespread applications like heterodyne detection, fiber optical sensors, and interplanetary coherent communications.

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APA 7

al, Z. Y. E. (2023). Microfiber evanescent-field photothermal gas detection using acoustic-induced mode-dependent frequency shift. https://doi.org/10.1515/nanoph-2023-0092

MLA

al, Zhu Yi et. "Microfiber evanescent-field photothermal gas detection using acoustic-induced mode-dependent frequency shift." 2023. https://doi.org/10.1515/nanoph-2023-0092.

Chicago

al, Zhu Yi et. 2023. "Microfiber evanescent-field photothermal gas detection using acoustic-induced mode-dependent frequency shift.". https://doi.org/10.1515/nanoph-2023-0092.

Harvard

al, Z. Y. E. 2023, Microfiber evanescent-field photothermal gas detection using acoustic-induced mode-dependent frequency shift, Wiley, available at: https://doi.org/10.1515/nanoph-2023-0092 [Accessed 29 Jun. 2026].

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Título
Microfiber evanescent-field photothermal gas detection using acoustic-induced mode-dependent frequency shift
Autor / colaboradores
Zhu Yi et al
Editorial
Wiley
Año de publicación
2023
ISSN
2192-8614
ISSN
2192-8614
Idioma
eng

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