Background-free broadband absorption spectroscopy based on interferometric suppression with a sign-inverted waveform
Author(s) -
Teemu Tomberg,
Andrey Muraviev,
Qitian Ru,
Konstantin L. Vodopyanov
Publication year - 2019
Publication title -
optica
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 5.074
H-Index - 107
ISSN - 2334-2536
DOI - 10.1364/optica.6.000147
Subject(s) - interferometry , optics , spectroscopy , fourier transform spectroscopy , broadband , absorption spectroscopy , laser , sensitivity (control systems) , absorption (acoustics) , detector , dynamic range , materials science , fourier transform , fourier transform infrared spectroscopy , physics , electronic engineering , quantum mechanics , engineering
Background-free methods have potentially superior detection sensitivity because of their ability to take advantage of the full laser power; they are therefore attractive to spectroscopists. We implement background-free Fourier transform spectroscopy based on coherent suppression of the background using an interferometer, whereby the central peak of the interferogram is suppressed without losing molecular absorption signatures. This results in the appearance of peaks rather than dips in the measured spectrum. The technique can be used with a variety of broadband spectroscopies and features advantages such as a reduction in the required detector dynamic range, the capability to perform quantitative measurements, and strongly enhanced sensitivity down to the quantum limit. We validated our method experimentally by performing mid-infrared dual-comb spectroscopy with a mixture of multiple molecular species over a broad wavelength range of 3–5 μm.
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