The achromatic chessboard, a new concept of a phase shifter for nulling interferometry

Rouan, D.; Pelat, D.

doi:10.1051/0004-6361:20078712

Cited by 12 publications

(3 citation statements)

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“…Several concepts were already proposed to solve this problem. We previously presented a new concept for providing such a functionality, which allows a simple and symmetric design of the interferometer, with only one device per beam in Paper I (Rouan & Pelat 2008) and Paper II . This is based on a pair of square cellular mirrors that looks like chessboards.…”

Section: Introductionmentioning

confidence: 99%

The achromatic chessboard, a new concept of a phase shifter for nulling interferometry

Pickel¹,

Pelat²,

Rouan³

et al. 2013

A&A

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Context. To find evidence one day of life on extra solar planets, one will have to directly detect photons of the exoplanet to obtain spectra and to look for specific spectroscopic features. One possible technique is dark fringe interferometry with several telescopes in space. This type of interferometry requires an achromatic π phase shift in one arm of an interferometer. We have already presented a concept of a quasi-achromatic phase shifter that is made of two cellular mirrors in which each cell position and phase shift is specific, so that the behavior of the null depth as a function of the wavelength is flat within a broad range. Aims. We want to experimentally validate this concept of an achromatic phase shifter and measure its performance in two different cases: a transmissive mask, which is made in bulk optics that are machined with ion etching and a reflective one, which is made by using a commercial segmented deformable mirror that is properly controlled. Methods. We assembled a dedicated optical bench, nicknamed DAMNED, to assess the concept and characterize its performance in the visible and to determine the limitations of this phase shifter. We analyze its performance by comparing the experimental results with a numerical instrument model. Results. We tested several transmissive masks and a reflective one. We reached an attenuation of about 2 × 10 −3 with a white source (Δλ = 430 to 830 nm) that proved to be the actual achromatic behavior of the phase shifter, despite its modest value. Extrapolated to mid-IR, its performance would be within typical specifications of a space mission as Darwin.

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Section: Introductionmentioning

confidence: 99%

The achromatic chessboard, a new concept of a phase shifter for nulling interferometry

Pickel¹,

Pelat²,

Rouan³

et al. 2013

A&A

Self Cite

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“…The main obstacle of its development is the technical difficulty to detect directly exoplanets, in order to locate them on their orbit and to take spectra. The technical challenge is to detect an object which is about 10 6 fainter than the star in the mid-infrared (and about10 9 in the visible), with an angular separation of 0.1 arcsec. Today there are two known ways to achieve this goal.…”

Section: Introductionmentioning

confidence: 99%

“…The dark fringe interferometry must include a device which induces an achromatic phase shift of π, and this is precisely what the device presented in this article does. The principles of this device were exposed in several previous publications [6][7][8][9] . It can be depicted as two square grids of cellular phase shifters, which are glass plates whose thickness and location are precisely defined.…”

Section: Introductionmentioning

confidence: 99%

The achromatic chessboard, a new concept of a phase shifter for nulling interferometry III: experimental performances

Pickel¹,

Rouan²,

Pelat³

et al. 2010

SPIE Proceedings

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Context. Dark fringe interferometry in the thermal infrared is one way to detect directly a planet orbiting a star, and so to characterize the planet's atmosphere through spectroscopy. This method demands a phase shift of π 1 in one arm of the interferometer. In order to detect various bio-tracers gases, a broad wavelength range (6-18 µm) 2-3 is necessary, therefore an achromatic phase shift of π is required. The achromatic device presented here is a phase shifter made of two cellular mirrors, in which each cell induces a specific phase shift. Aims. We wish to demonstrate that this theoretical concept is experimentally valid. We present in this paper the setup and the very first results. Methods. In a first step, we have consolidated the theoretical ground and in a second step we developed an optical bench in the visible domain to test the concept and measure the performances of this device. Results. The preliminary experimental tests show evidences that such a device is working as expected in terms of nulling and achromatism: in spite of an error on one cell of the prototype, it provides a nulling of 2.10 −3 at one wavelength, and this value is close to the expected value. Besides, a nulling of 1.10 −2 in a 450 to 750 nm bandwidth: a hint that a perfect device should be achromatic.

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Nulling Interferometry

Rouan¹

2014

Encyclopedia of Astrobiology

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The achromatic chessboard, a new concept of a phase shifter for nulling interferometry

Cited by 12 publications

References 13 publications

The achromatic chessboard, a new concept of a phase shifter for nulling interferometry

The achromatic chessboard, a new concept of a phase shifter for nulling interferometry

The achromatic chessboard, a new concept of a phase shifter for nulling interferometry III: experimental performances

Nulling Interferometry

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