Wavefront sensing for evaluation of extreme ultraviolet microscopy

Mabel Ruiz-Lopez; Masoud Mehrjoo; Barbara Keitel; Elke Plönjes; Domenico Alj; Guillaume Dovillaire; Lu Li; Philippe Zeitoun

doi:10.3390/s20226426

Wavefront sensing for evaluation of extreme ultraviolet microscopy

Mabel Ruiz-Lopez
, Masoud Mehrjoo
, Barbara Keitel
, Elke Plönjes
, Domenico Alj
, Guillaume Dovillaire
, Lu Li
, Philippe Zeitoun

Résultats de recherche: Contribution à un journal › Lettre › Revue par des pairs

Résumé

Wavefront analysis is a fast and reliable technique for the alignment and characterization of optics in the visible, but also in the extreme ultraviolet (EUV) and X-ray regions. However, the technique poses a number of challenges when used for optical systems with numerical apertures (NA) > 0.1. A high-numerical-aperture Hartmann wavefront sensor was employed at the free electron laser FLASH for the characterization of a Schwarzschild objective. These are widely used in EUV to achieve very small foci, particularly for photolithography. For this purpose, Schwarzschild objectives require highly precise alignment. The phase measurements acquired with the wavefront sensor were analyzed employing two different methods, namely, the classical calculation of centroid positions and Fourier demodulation. Results from both approaches agree in terms of wavefront maps with negligible degree of discrepancy.

langue originale	Anglais
Numéro d'article	6426
Pages (de - à)	1-13
Nombre de pages	13
journal	Sensors (Switzerland)
Volume	20
Numéro de publication	22
Les DOIs	https://doi.org/10.3390/s20226426
état	Publié - 2 nov. 2020

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10.3390/s20226426

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title = "Wavefront sensing for evaluation of extreme ultraviolet microscopy",

abstract = "Wavefront analysis is a fast and reliable technique for the alignment and characterization of optics in the visible, but also in the extreme ultraviolet (EUV) and X-ray regions. However, the technique poses a number of challenges when used for optical systems with numerical apertures (NA) > 0.1. A high-numerical-aperture Hartmann wavefront sensor was employed at the free electron laser FLASH for the characterization of a Schwarzschild objective. These are widely used in EUV to achieve very small foci, particularly for photolithography. For this purpose, Schwarzschild objectives require highly precise alignment. The phase measurements acquired with the wavefront sensor were analyzed employing two different methods, namely, the classical calculation of centroid positions and Fourier demodulation. Results from both approaches agree in terms of wavefront maps with negligible degree of discrepancy.",

keywords = "Extreme ultraviolet, Optical metrology, Schwarzschild objective, Wavefront sensor",

author = "Mabel Ruiz-Lopez and Masoud Mehrjoo and Barbara Keitel and Elke Pl{\"o}njes and Domenico Alj and Guillaume Dovillaire and Lu Li and Philippe Zeitoun",

note = "Publisher Copyright: {\textcopyright} 2020 by the authors. Licensee MDPI, Basel, Switzerland.",

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month = nov,

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doi = "10.3390/s20226426",

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T1 - Wavefront sensing for evaluation of extreme ultraviolet microscopy

AU - Ruiz-Lopez, Mabel

AU - Mehrjoo, Masoud

AU - Keitel, Barbara

AU - Plönjes, Elke

AU - Alj, Domenico

AU - Dovillaire, Guillaume

AU - Li, Lu

AU - Zeitoun, Philippe

PY - 2020/11/2

Y1 - 2020/11/2

N2 - Wavefront analysis is a fast and reliable technique for the alignment and characterization of optics in the visible, but also in the extreme ultraviolet (EUV) and X-ray regions. However, the technique poses a number of challenges when used for optical systems with numerical apertures (NA) > 0.1. A high-numerical-aperture Hartmann wavefront sensor was employed at the free electron laser FLASH for the characterization of a Schwarzschild objective. These are widely used in EUV to achieve very small foci, particularly for photolithography. For this purpose, Schwarzschild objectives require highly precise alignment. The phase measurements acquired with the wavefront sensor were analyzed employing two different methods, namely, the classical calculation of centroid positions and Fourier demodulation. Results from both approaches agree in terms of wavefront maps with negligible degree of discrepancy.

AB - Wavefront analysis is a fast and reliable technique for the alignment and characterization of optics in the visible, but also in the extreme ultraviolet (EUV) and X-ray regions. However, the technique poses a number of challenges when used for optical systems with numerical apertures (NA) > 0.1. A high-numerical-aperture Hartmann wavefront sensor was employed at the free electron laser FLASH for the characterization of a Schwarzschild objective. These are widely used in EUV to achieve very small foci, particularly for photolithography. For this purpose, Schwarzschild objectives require highly precise alignment. The phase measurements acquired with the wavefront sensor were analyzed employing two different methods, namely, the classical calculation of centroid positions and Fourier demodulation. Results from both approaches agree in terms of wavefront maps with negligible degree of discrepancy.

KW - Extreme ultraviolet

KW - Optical metrology

KW - Schwarzschild objective

KW - Wavefront sensor

UR - https://www.scopus.com/pages/publications/85096034632

U2 - 10.3390/s20226426

DO - 10.3390/s20226426

M3 - Letter

C2 - 33182797

AN - SCOPUS:85096034632

SN - 1424-8220

VL - 20

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EP - 13

JO - Sensors (Switzerland)

JF - Sensors (Switzerland)

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ER -

Wavefront sensing for evaluation of extreme ultraviolet microscopy

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