Doppler broadened noise-immune cavity-enhanced optical heterodyne molecular spectrometry: optimum modulation and demodulation conditions, cavity length, and modulation order

Ehlers, Patrick; Silander, Isak; Axner, Ove

doi:10.1364/josab.31.002051

Cited by 17 publications

(23 citation statements)

References 24 publications

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“…where χ NO G ν c is the NICE-OHMS dispersion line shape function that is given by a combination of individual line shape functions that can be written as [11,19] …”

Section: Research Articlementioning

confidence: 99%

“…However, although Db NICE-OHMS already has been realized with previously found optimum conditions regarding signal strength [11,19] and reduction of etalons by the use of etalon immune distances (EIDs) [20], resulting in the system used in [16], Allan-Werle plots are in this work used to analyze the limiting factors of this NICE-OHMS setup [16]. By the knowledge gained from this analysis, as well as the noise incoupling model developed, two remaining causes of noise and background signals were identified.…”

Section: Introductionmentioning

confidence: 99%

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Model for in-coupling of etalons into signal strengths extracted from spectral line shape fitting and methodology for predicting the optimum scanning range—demonstration of Doppler-broadened, noise-immune, cavity-enhanced optical heterodyne molecular spectroscopy down to 9 × 10^−14 cm^−1

2015

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Expressions for the in-coupling of white noise and etalons into fitted signal strengths are derived. These show that the amount of noise picked up is affected by the scanning range. A methodology for finding the optimum scanning range from a single set of measurements has been developed. This was used to estimate the optimum conditions of a noise-immune, cavity-enhanced optical heterodyne molecular spectroscopy (NICE-OHMS) setup. The methodology was validated by measurements. This resulted in a spectral noise equivalent absorption per unit length of 2.6 × 10 −13 cm −1 Hz −1∕2 and a minimum Allan deviation of 9 × 10 −14 cm −1 at 30 s, which are, to our knowledge, the lowest reported for Doppler-broadened NICE-OHMS.

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“…where χ NO G ν c is the NICE-OHMS dispersion line shape function that is given by a combination of individual line shape functions that can be written as [11,19] …”

Section: Research Articlementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Model for in-coupling of etalons into signal strengths extracted from spectral line shape fitting and methodology for predicting the optimum scanning range—demonstration of Doppler-broadened, noise-immune, cavity-enhanced optical heterodyne molecular spectroscopy down to 9 × 10^−14 cm^−1

2015

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“…As recently discussed in an accompanying work [4], the technique relies on a fairly large number of entities [5,6], which makes it nontrivial to assess these conditions. However, since it utilizes frequency modulation (FM) for reduction of technical noise, some of its properties are given by those of that technique.…”

Section: Introductionmentioning

confidence: 99%

“…To remedy this, Ehlers et al [4] recently derived a coherent description of Db-NICE-OHMS that encompasses the most relevant parameters-ν m , β, θ, the cavity length (L), and k-and can serve as a basis for assessment of the optimum design or detection conditions of the technique. Their analysis covered the cases when an existing NICE-OHMS system, based on an existing cavity, is to be optimized and when a NICE-OHMS system is to be designed from scratch for transitions in the Doppler limit and for the specific case with equal amounts of collision and Doppler broadening.…”

Section: Introductionmentioning

confidence: 99%

Doppler broadened NICE-OHMS beyond the triplet formalism: assessment of optimum modulation index

et al. 2014

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The dependence of Doppler broadened noise-immune cavity-enhanced optical heterodyne molecular spectrometry (NICE-OHMS) on the modulation index, β, has been investigated experimentally on C 2 H 2 and CO 2 , both in the absence and the presence of optical saturation. It is shown that the maximum signals are obtained for β that produce more than one pair of sidebands: in the Doppler limit and for the prevailing conditions (unsaturated transition and the pertinent modulation frequency and Doppler widths) around 1 and 1.4 for the dispersion and absorption detection phases, respectively. The results verify predictions given in an accompanying work. It is also shown that there is no substantial broadening of the NICE-OHMS signal for β < 1. The use of β of unity has yielded a Db-NICE-OHMS detection sensitivity of 4.9 × 10 −12 cm −1 Hz −1∕2 , which is the lowest (best) value so far achieved for NICE-OHMS based on a tunable laser. The number of sidebands that needs to be included in fits of the line-shape function to obtain good accuracy has been assessed. It is concluded that it is enough to consider three pairs of sidebands whenever the systematic errors in a concentration assessment should be below 1% when β < 2 are used and <1‰ for β < 1.5.

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“…Low-frequency feedback (up to 1 kHz) is fed directly to the piezo in the EDFL. The f -EOM, which is equipped with a proton-exchanged waveguide to minimize the generation of RAM, is modulated by two radio frequency signals-one at 20 MHz and another at 380 MHz-to generate the sidebands for the PDH locking and the FMS with modulation indices of 0.1 and 1, respectively, the latter chosen to maximize the NICE-OHMS signal [29]. Before impinging onto the cavity, the laser propagates through an isolator (ISO), a half-wave plate (λ∕2), a modematching lens, a PBS, and a quarter-wave plate (λ∕4).…”

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confidence: 99%

Shot-noise-limited Doppler-broadened noise-immune cavity-enhanced optical heterodyne molecular spectrometry

Gang

Hausmaninger

et al. 2018

Opt. Lett.

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Shot-noise-limited Doppler-broadened (Db) noise-immune cavity-enhanced optical heterodyne molecular spectrometry (NICE-OHMS) has been realized by implementation of balanced detection. A characterization of the system based on Allan-Werle plots of the absorption coefficient, retrieved by fitting a model function to data, shows that the system has a white noise equivalent absorption per unit length per square root of bandwidth of 2.3 × 10 −13 cm −1 Hz −1∕2 , solely 44% above the shot noise limit, and a detection sensitivity of 2.2 × 10 −14 cm −1 over 200 s, both being unprecedented for Db NICE-OHMS. The white noise response follows the expected inverse square root dependence on power that is representative of a shot-noise-limited response, which confirms that the system is shot-noiselimited.

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Doppler broadened noise-immune cavity-enhanced optical heterodyne molecular spectrometry: optimum modulation and demodulation conditions, cavity length, and modulation order

Cited by 17 publications

References 24 publications

Model for in-coupling of etalons into signal strengths extracted from spectral line shape fitting and methodology for predicting the optimum scanning range—demonstration of Doppler-broadened, noise-immune, cavity-enhanced optical heterodyne molecular spectroscopy down to 9 × 10^−14 cm^−1

Model for in-coupling of etalons into signal strengths extracted from spectral line shape fitting and methodology for predicting the optimum scanning range—demonstration of Doppler-broadened, noise-immune, cavity-enhanced optical heterodyne molecular spectroscopy down to 9 × 10^−14 cm^−1

Doppler broadened NICE-OHMS beyond the triplet formalism: assessment of optimum modulation index

Shot-noise-limited Doppler-broadened noise-immune cavity-enhanced optical heterodyne molecular spectrometry

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