Wavelength-scale stationary-wave integrated Fourier-transform spectrometry

Coarer, E. Le; Blaize, Sylvain; Bénech, Pierre; Stefanon, Ilan; Morand, Alain; Lérondel, Gilles; Leblond, Grégory; Kern, P.; Fédéli, Jean Marc; Royer, Pascal

doi:10.1038/nphoton.2007.138

Cited by 201 publications

(155 citation statements)

References 15 publications

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“…Such ultrahigh-frequency dispersion could be used for a compact high spectral resolution spectrometer, similar to compact atomic clocks and magnetometers [29]. The prism has a huge angular dispersion (dθ/dλ = 10 3 nm −1 ), which can spatially resolve spectral widths of a few kilohertz, with a corresponding spectral resolution R = λ/δλ 10 12 (One can see that our approach hold promise; indeed recently, for example, the 1-mm-length spectrometer has shown a resolution of 400 [28]). We have observed the angle of deviation to be an order of magnitude larger than the one previously observed in an inhomogeneous magnetic field [18].…”

Section: Resultsmentioning

confidence: 87%

Ultradispersive adaptive prism based on a coherently prepared atomic medium

Sautenkov

Rostovtsev

et al. 2010

Phys. Rev. A

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We have experimentally demonstrated an ultra-dispersive optical prism made from a coherently driven Rb atomic vapor. The prism possesses spectral angular dispersion that is 6 orders of magnitude higher than that of a prism made of optical glass; such angular dispersion allows one to spatially resolve light beams with different frequencies separated by a few kilohertz. The prism operates near the resonant frequency of atomic vapor and its dispersion is optically controlled by a coherent driving field.

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Section: Resultsmentioning

confidence: 87%

Ultradispersive adaptive prism based on a coherently prepared atomic medium

Sautenkov

Rostovtsev

et al. 2010

Phys. Rev. A

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“…6. takes advantage of the new developments in integrated optics, permitting both beam recombination and spectrography, thus avoiding the losses at all the diopters of bulk optics used for beam transportation and in the spectrograph. Such a concept, derived from on-going developments for visible spectroscopy (Le Coarer et al 2007) is under investigation ) and can be envision on the sky in the coming few years.…”

Section: Towards a Dedicated Instrumentmentioning

confidence: 99%

Phase closure nulling

Chelli¹,

Duvert²,

Malbet³

et al. 2009

A&A

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We provide a complete theory of the phase closure of a binary system in which a small, feeble, and unresolved companion acts as a perturbing parameter on the spatial frequency spectrum of a dominant, bright, resolved source. We demonstrate that the influence of the companion can be measured with precision by measuring the phase closure of the system near the nulls of the primary visibility function. In these regions of phase closure nulling, frequency intervals always exist where the phase closure signature of the companion is larger than any systematic error and can then be measured. We show that this technique allows retrieval of many astrophysically relevant properties of faint and close companions such as flux, position, and in favorable cases, spectrum. We conclude by a rapid study of the potentialities of phase closure nulling observations with current interferometers and explore the requirements for a new type of dedicated instrument.

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“…If one compares this expression to what is found in the original SWIFTs design [6], one can find that we are actually stretching the interferogram by a factor of 2n e f f /Δn e f f , which makes the period as large as several tens of micrometers. Consequently, it is now easy to find photodiode arrays that are commercially available and that have a pixel pitch small enough to avoid subsampling of the interferogram.…”

Section: Principle Of the Co-propagative Stationary Ftsmentioning

confidence: 89%

“…Although there exist various miniaturized Fourier transform spectrometers that still involve moving components [3][4][5], it would be better to have an FTS without any moving components. Currently, integrated FTS that are implemented without any moving components can be divided mainly into two categories: the stationary wave integrated FTS (SWIFTs) [6] and the spatial heterodyne spectrometer (SHS) [7].…”

Section: Introductionmentioning

confidence: 99%

“…On top of the waveguide, nano-scatterers are carefully positioned to couple this interference pattern to a detector array. As introduced in the work of Etienne le Coarer et al [6], the pitch of the interference pattern can be expressed as λ/(2n e f f ) which is much smaller than the pitch size of state-of-the-art photodiode arrays. As a result, the interferogram is subsampled, leading to a limitation on the spectral bandwidth of the FTS.…”

Section: Introductionmentioning

confidence: 99%

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CMOS-compatible broadband co-propagative stationary Fourier transform spectrometer integrated on a silicon nitride photonics platform

et al. 2017

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Abstract:We demonstrate a novel type of Fourier Transform Spectrometer (FTS) that can be realized with CMOS compatible fabrication techniques. This FTS contains no moving components and is based on the direct detection of the interferogram generated by the interference of the evanescent fields of two co-propagating waveguide modes. The theoretical analysis indicates that this type of FTS inherently has a large bandwidth (>100 nm). The first prototype that is integrated on a Si 3 N 4 waveguide platform is demonstrated and has an extremely small size (0.1 mm 2 ). We introduce the operation principle and report on the preliminary experiments. The results show a moderately high resolution (6 nm) which is in good agreement with the theoretical prediction.

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Wavelength-scale stationary-wave integrated Fourier-transform spectrometry

Cited by 201 publications

References 15 publications

Ultradispersive adaptive prism based on a coherently prepared atomic medium

Ultradispersive adaptive prism based on a coherently prepared atomic medium

Phase closure nulling

CMOS-compatible broadband co-propagative stationary Fourier transform spectrometer integrated on a silicon nitride photonics platform

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