Methane sensing via unbalanced nonlinear interferometry using a CMOS camera and undetected mid-infrared light

Jinghan Dong; Arthur C. Cardoso; Haichen Zhou; Jingrui Zhang; Weijie Nie; Alex S. Clark; John G. Rarity

doi:10.1063/5.0242197

Methane sensing via unbalanced nonlinear interferometry using a CMOS camera and undetected mid-infrared light

Jinghan Dong^*, Arthur C. Cardoso, Haichen Zhou, Jingrui Zhang, Weijie Nie, Alex S. Clark, John G. Rarity

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

Here, we present a high-sensitivity, rapid, and low-cost method for methane sensing based on a nonlinear interferometer. This method utilizes signal photons generated by stimulated parametric downconversion (ST-PDC), enabling the use of a silicon detector to capture high-precision methane absorption spectra in the mid-infrared region. By controlling the system loss, we achieve more significant changes in visibility, thereby increasing sensitivity. A low-cost CMOS camera is employed to capture spatial interference fringes, ensuring fast and efficient detection. Thereby, we demonstrate an accurate measurement of methane concentration within a gas cell. In addition, we show that ST-PDC enables long-distance sensing and the capability to measure open-path low ambient methane concentrations in the real world.

Original language	English
Article number	061104
Number of pages	6
Journal	Applied Physics Letters
Volume	126
Issue number	6
DOIs	https://doi.org/10.1063/5.0242197
Publication status	Published - 10 Feb 2025

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title = "Methane sensing via unbalanced nonlinear interferometry using a CMOS camera and undetected mid-infrared light",

abstract = "Here, we present a high-sensitivity, rapid, and low-cost method for methane sensing based on a nonlinear interferometer. This method utilizes signal photons generated by stimulated parametric downconversion (ST-PDC), enabling the use of a silicon detector to capture high-precision methane absorption spectra in the mid-infrared region. By controlling the system loss, we achieve more significant changes in visibility, thereby increasing sensitivity. A low-cost CMOS camera is employed to capture spatial interference fringes, ensuring fast and efficient detection. Thereby, we demonstrate an accurate measurement of methane concentration within a gas cell. In addition, we show that ST-PDC enables long-distance sensing and the capability to measure open-path low ambient methane concentrations in the real world.",

author = "Jinghan Dong and Cardoso, {Arthur C.} and Haichen Zhou and Jingrui Zhang and Weijie Nie and Clark, {Alex S.} and Rarity, {John G.}",

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T1 - Methane sensing via unbalanced nonlinear interferometry using a CMOS camera and undetected mid-infrared light

AU - Dong, Jinghan

AU - Cardoso, Arthur C.

AU - Zhou, Haichen

AU - Zhang, Jingrui

AU - Nie, Weijie

AU - Clark, Alex S.

AU - Rarity, John G.

PY - 2025/2/10

Y1 - 2025/2/10

N2 - Here, we present a high-sensitivity, rapid, and low-cost method for methane sensing based on a nonlinear interferometer. This method utilizes signal photons generated by stimulated parametric downconversion (ST-PDC), enabling the use of a silicon detector to capture high-precision methane absorption spectra in the mid-infrared region. By controlling the system loss, we achieve more significant changes in visibility, thereby increasing sensitivity. A low-cost CMOS camera is employed to capture spatial interference fringes, ensuring fast and efficient detection. Thereby, we demonstrate an accurate measurement of methane concentration within a gas cell. In addition, we show that ST-PDC enables long-distance sensing and the capability to measure open-path low ambient methane concentrations in the real world.

AB - Here, we present a high-sensitivity, rapid, and low-cost method for methane sensing based on a nonlinear interferometer. This method utilizes signal photons generated by stimulated parametric downconversion (ST-PDC), enabling the use of a silicon detector to capture high-precision methane absorption spectra in the mid-infrared region. By controlling the system loss, we achieve more significant changes in visibility, thereby increasing sensitivity. A low-cost CMOS camera is employed to capture spatial interference fringes, ensuring fast and efficient detection. Thereby, we demonstrate an accurate measurement of methane concentration within a gas cell. In addition, we show that ST-PDC enables long-distance sensing and the capability to measure open-path low ambient methane concentrations in the real world.

U2 - 10.1063/5.0242197

DO - 10.1063/5.0242197

M3 - Article (Academic Journal)

SN - 0003-6951

VL - 126

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 6

M1 - 061104

ER -

Methane sensing via unbalanced nonlinear interferometry using a CMOS camera and undetected mid-infrared light

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