X-ray–ultraviolet beam splitters for the Michelson interferometer

Franck Delmotte; Marie Françoise Ravet; Françoise Bridou; Françoise Varniè; Philippe Zeitoun; Seébastien Hubert; Laurent Vanbostal; Gérard Soullie

doi:10.1364/AO.41.005905

X-ray–ultraviolet beam splitters for the Michelson interferometer

Franck Delmotte
, Marie Françoise Ravet
, Françoise Bridou
, Françoise Varniè
, Philippe Zeitoun
, Seébastien Hubert
, Laurent Vanbostal
, Gérard Soullie

Research output: Contribution to journal › Article › peer-review

Abstract

With the aim of realizing a Michelson interferometer working at 13.9 nm, we have developed a symmetrical beam splitter with multilayers deposited on the front and back sides of a silicon nitride membrane. On the basis of the experimental optical properties of the membrane, simulations have been performed to define the multilayer structure that provides the highest reflectivity–transmission product. Optimized Mo–Si multilayers have been successfully deposited on both sides of the membrane by use of the ion-beam sputtering technique, with a thickness-period reproducibility of 0.1 nm. Measurements by means of synchrotron radiation at 13.9 nm and at an angle of 45° provide a reflectivity of 14.2% and a transmission of 15.2% for a 60% s-polarized light, close to the simulated values. Such a beam splitter has been used for x-ray laser Michelson interferometry at 13.9 nm. The first interferogram is discussed.

Original language	English
Pages (from-to)	5905-5912
Number of pages	8
Journal	Applied Optics
Volume	41
Issue number	28
DOIs	https://doi.org/10.1364/AO.41.005905
Publication status	Published - 1 Oct 2002

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title = "X-ray–ultraviolet beam splitters for the Michelson interferometer",

abstract = "With the aim of realizing a Michelson interferometer working at 13.9 nm, we have developed a symmetrical beam splitter with multilayers deposited on the front and back sides of a silicon nitride membrane. On the basis of the experimental optical properties of the membrane, simulations have been performed to define the multilayer structure that provides the highest reflectivity–transmission product. Optimized Mo–Si multilayers have been successfully deposited on both sides of the membrane by use of the ion-beam sputtering technique, with a thickness-period reproducibility of 0.1 nm. Measurements by means of synchrotron radiation at 13.9 nm and at an angle of 45° provide a reflectivity of 14.2\% and a transmission of 15.2\% for a 60\% s-polarized light, close to the simulated values. Such a beam splitter has been used for x-ray laser Michelson interferometry at 13.9 nm. The first interferogram is discussed.",

author = "Franck Delmotte and Ravet, \{Marie Fran{\c c}oise\} and Fran{\c c}oise Bridou and Fran{\c c}oise Varni{\`e} and Philippe Zeitoun and Se{\'e}bastien Hubert and Laurent Vanbostal and G{\'e}rard Soullie",

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T1 - X-ray–ultraviolet beam splitters for the Michelson interferometer

AU - Delmotte, Franck

AU - Ravet, Marie Françoise

AU - Bridou, Françoise

AU - Varniè, Françoise

AU - Zeitoun, Philippe

AU - Hubert, Seébastien

AU - Vanbostal, Laurent

AU - Soullie, Gérard

PY - 2002/10/1

Y1 - 2002/10/1

N2 - With the aim of realizing a Michelson interferometer working at 13.9 nm, we have developed a symmetrical beam splitter with multilayers deposited on the front and back sides of a silicon nitride membrane. On the basis of the experimental optical properties of the membrane, simulations have been performed to define the multilayer structure that provides the highest reflectivity–transmission product. Optimized Mo–Si multilayers have been successfully deposited on both sides of the membrane by use of the ion-beam sputtering technique, with a thickness-period reproducibility of 0.1 nm. Measurements by means of synchrotron radiation at 13.9 nm and at an angle of 45° provide a reflectivity of 14.2% and a transmission of 15.2% for a 60% s-polarized light, close to the simulated values. Such a beam splitter has been used for x-ray laser Michelson interferometry at 13.9 nm. The first interferogram is discussed.

AB - With the aim of realizing a Michelson interferometer working at 13.9 nm, we have developed a symmetrical beam splitter with multilayers deposited on the front and back sides of a silicon nitride membrane. On the basis of the experimental optical properties of the membrane, simulations have been performed to define the multilayer structure that provides the highest reflectivity–transmission product. Optimized Mo–Si multilayers have been successfully deposited on both sides of the membrane by use of the ion-beam sputtering technique, with a thickness-period reproducibility of 0.1 nm. Measurements by means of synchrotron radiation at 13.9 nm and at an angle of 45° provide a reflectivity of 14.2% and a transmission of 15.2% for a 60% s-polarized light, close to the simulated values. Such a beam splitter has been used for x-ray laser Michelson interferometry at 13.9 nm. The first interferogram is discussed.

U2 - 10.1364/AO.41.005905

DO - 10.1364/AO.41.005905

M3 - Article

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SN - 1559-128X

VL - 41

SP - 5905

EP - 5912

JO - Applied Optics

JF - Applied Optics

IS - 28

ER -

X-ray–ultraviolet beam splitters for the Michelson interferometer

Abstract

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