Sensitive and broadband measurement of dispersion in a cavity using a Fourier transform spectrometer with kHz resolution

Rutkowski, Lucile; Johansson, Alexandra C.; Gang, Zhao; Hausmaninger, Thomas; Khodabakhsh, Amir; Axner, Ove; Foltynowicz, Aleksandra

doi:10.1364/oe.25.021711

Cited by 44 publications

(26 citation statements)

References 25 publications

(38 reference statements)

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“…If needed, spectral features narrower than f rep can be measured with no ILS distortion using the method of comb-based FTS with sub-nominal resolution, in which interferograms with length matched precisely to c/f rep are measured. 23,28,29 The detection limit of OFC-PAS can be improved by several measures. First of all, a factor of 40 improvement can be expected using available high-power mid-IR OFC sources 30 with an output power of up to 1.5 W, compared to 36 mW of the signal comb used in this work.…”

Section: Discussionmentioning

confidence: 99%

“…Using an optical frequency comb (OFC) as a light source for Fourier transform spectrometers (FTS), in the so-called combbased FTS, allows much faster acquisition (of the order of seconds) of spectra with high signal-to-noise ratio (S/N), 22 and resolution down to kHz range with no ILS contribution. 23 Here, we report the first demonstration of photoacoustic spectroscopy using an optical frequency comb. We call the technique: optical frequency comb photoacoustic spectroscopy (OFC-PAS).…”

Section: Introductionmentioning

confidence: 93%

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Optical Frequency Comb Photoacoustic Spectroscopy

Sadiek¹,

Mikkonen²,

Vainio³

et al. 2019

Conference on Lasers and Electro-Optics

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We report the first photoacoustic detection scheme using an optical frequency comb -the optical frequency comb photoacoustic spectroscopy (OFC-PAS). OFC-PAS combines the broad spectral coverage and the high resolution of OFCs with the small sample volume of cantilever-enhanced PA detection. In OFC-PAS, a Fourier transform spectrometer (FTS) is used to modulate the intensity of the exciting comb source at a frequency determined by its scanning speed. One of the FTS outputs is directed to the PA cell and the other is measured simultaneously with a photodiode and used to normalize the PA signal. The cantilever-enhanced PA detector operates in a non-resonant mode, enabling detection of broadband frequency response. The broadband and the high-resolution capabilities of OFC-PAS are demonstrated by measuring the rovibrational spectra of the fundamental C-H stretch band of CH 4 , with no instrumental line shape distortions, at total pressures of 1000 mbar, 650 mbar, and 400 mbar. In this first demonstration, a spectral resolution two orders of magnitude higher than previously reported with broadband PAS is obtained, limited by the pressure broadening. A limit of detection of 0.8 ppm of methane in N 2 is accomplished in a single interferogram measurement (200 s measurement time, 1000 MHz spectral resolution, 1000 mbar total pressure) for an exciting power spectral density of 42 µW/cm -1 . A normalized noise equivalent absorption of 8 × 10 -10 W cm -1 Hz -1/2 is obtained, which is only a factor of three higher than the best reported with PAS based on continuous wave lasers. A wide dynamic range of up to four orders of magnitude and a very good linearity (limited by the Beer-Lambert law) over two orders of magnitude are realized. OFC-PAS extends the capability of optical sensors for multispecies trace gas analysis in small sample volume with high resolution and selectivity.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 93%

Optical Frequency Comb Photoacoustic Spectroscopy

Sadiek¹,

Mikkonen²,

Vainio³

et al. 2019

Conference on Lasers and Electro-Optics

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“…With high acquisition rates (up to 2 × 1/Δ rep ) and a highthroughput data stream amenable to actively controlled coherent averaging [60], postprocessing [57], and/or adaptive sampling [58], deep averaging of fitted spectroscopic parameters is possible, and therefore so is high precision. Although intensity measurements of cavity transmission modes can also measure complex molecular response (via mode position and line width) [92][93][94][95], those techniques each require laser scanning, and therefore are inherently…”

Section: Discussionmentioning

confidence: 99%

Quantitative modeling of complex molecular response in coherent cavity-enhanced dual-comb spectroscopy

Fleisher

Long

Hodges

2018

Journal of Molecular Spectroscopy

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We present a complex-valued electric field model for experimentally observed cavity transmission in coherent cavity-enhanced (CE) multiplexed spectroscopy (i.e., dual-comb spectroscopy, DCS). The transmission model for CE-DCS differs from that previously derived for Fourier-transform CE direct frequency comb spectroscopy [Foltynowicz et al., Appl. Phys. B 110, 163–175 (2013)] by the treatment of the local oscillator which, in the case of CE-DCS, does not interact with the enhancement cavity. Validation is performed by measurements of complex-valued near-infrared spectra of CO and CO2 by an electro-optic frequency comb coherently coupled to an enhancement cavity of finesse F = 19600. Following validation, we measure the 30012 ← 00001 12C16O2 vibrational band origin with a combined standard uncertainty of 770 kHz (fractional uncertainty of 4 × 10−9).

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“…1, follows in large the one used in ref. [19]. The resonances of a Fabry-Perot cavity are probed by an Er:fiber frequency comb, and the light transmitted through the cavity is analyzed with a fast-scanning Fourier transform spectrometer (FTS) with sub-nominal resolution [18].…”

Section: Methodsmentioning

confidence: 99%

“…A Lorentzian function is fitted to each cavity mode to retrieve its center frequency, width, and amplitude. We have previously demonstrated that cavity mode frequencies can be used for highprecision retrieval of broadband intracavity group delay dispersion [19]. Here we utilize the full potential of cavity mode characterization and retrieve dispersion and absorption spectra of three combination bands of CO 2 from the cavity mode shifts and broadenings, as well as the corresponding cavity-enhanced transmission spectra from the cavity mode amplitudes.…”

Section: Introductionmentioning

confidence: 99%

Broadband calibration-free cavity-enhanced complex refractive index spectroscopy using a frequency comb

Johansson¹,

Rutkowski²,

Filipsson³

et al. 2018

Opt. Express

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We present broadband cavity-enhanced complex refractive index spectroscopy (CE-CRIS), a technique for calibration-free determination of the complex refractive index of entire molecular bands via direct measurement of transmission modes of a Fabry-Perot cavity filled with the sample. The measurement of the cavity transmission spectrum is done using an optical frequency comb and a mechanical Fourier transform spectrometer with sub-nominal resolution. Molecular absorption and dispersion spectra (corresponding to the imaginary and real parts of the refractive index) are obtained from the cavity mode broadening and shift retrieved from fits of Lorentzian profiles to the individual cavity modes. This method is calibration-free because the mode broadening and shift are independent of the cavity parameters such as the length and mirror reflectivity. In this first demonstration of broadband CE-CRIS we measure simultaneously the absorption and dispersion spectra of three combination bands of CO in the range between 1525 nm and 1620 nm and achieve good agreement with theoretical models. This opens up for precision spectroscopy of the complex refractive index of several molecular bands simultaneously.

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Sensitive and broadband measurement of dispersion in a cavity using a Fourier transform spectrometer with kHz resolution

Cited by 44 publications

References 25 publications

Optical Frequency Comb Photoacoustic Spectroscopy

Optical Frequency Comb Photoacoustic Spectroscopy

Quantitative modeling of complex molecular response in coherent cavity-enhanced dual-comb spectroscopy

Broadband calibration-free cavity-enhanced complex refractive index spectroscopy using a frequency comb

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