Plasma-assisted oxide removal from ruthenium-coated EUV optics

A. Dolgov; C.J. Lee; F. Bijkerk; A. Abrikosov; V. M. Krivtsun; D. Lopaev; O. Yakushev; M. van Kampen

doi:10.1063/1.5006771

Plasma-assisted oxide removal from ruthenium-coated EUV optics

A. Dolgov, C.J. Lee, F. Bijkerk, A. Abrikosov, V. M. Krivtsun, D. Lopaev, O. Yakushev, M. van Kampen

Elementary Processes in Gas Discharges

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

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An experimental study of oxide reduction at the surface of ruthenium layers on top of multilayer mirrors and thin Ru/Si films is presented. Oxidation and reduction processes were observed under conditions close to those relevant for extreme ultraviolet lithography. The oxidized ruthenium surface was exposed to a low-temperature hydrogen plasma, similar to the plasma induced by extreme ultraviolet radiation. The experiments show that hydrogen ions are the main reducing agent. Furthermore, the addition of hydrogen radicals increases the reduction rate beyond that expected from simple flux calculations. We show that low-temperature hydrogen plasmas can be effective for reducing oxidized top surfaces. Our proof-of-concept experiments show that an in situ, EUV-generated plasma cleaning technology is feasible.

Originele taal-2	Engels
Artikelnummer	153301
Aantal pagina's	9
Tijdschrift	Journal of Applied Physics
Volume	123
Nummer van het tijdschrift	15
DOI's	https://doi.org/10.1063/1.5006771
Status	Gepubliceerd - 21 apr. 2018

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abstract = "An experimental study of oxide reduction at the surface of ruthenium layers on top of multilayer mirrors and thin Ru/Si films is presented. Oxidation and reduction processes were observed under conditions close to those relevant for extreme ultraviolet lithography. The oxidized ruthenium surface was exposed to a low-temperature hydrogen plasma, similar to the plasma induced by extreme ultraviolet radiation. The experiments show that hydrogen ions are the main reducing agent. Furthermore, the addition of hydrogen radicals increases the reduction rate beyond that expected from simple flux calculations. We show that low-temperature hydrogen plasmas can be effective for reducing oxidized top surfaces. Our proof-of-concept experiments show that an in situ, EUV-generated plasma cleaning technology is feasible.",

author = "A. Dolgov and C.J. Lee and F. Bijkerk and A. Abrikosov and Krivtsun, {V. M.} and D. Lopaev and O. Yakushev and {van Kampen}, M.",

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AU - Dolgov, A.

AU - Lee, C.J.

AU - Bijkerk, F.

AU - Abrikosov, A.

AU - Krivtsun, V. M.

AU - Lopaev, D.

AU - Yakushev, O.

AU - van Kampen, M.

PY - 2018/4/21

Y1 - 2018/4/21

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AB - An experimental study of oxide reduction at the surface of ruthenium layers on top of multilayer mirrors and thin Ru/Si films is presented. Oxidation and reduction processes were observed under conditions close to those relevant for extreme ultraviolet lithography. The oxidized ruthenium surface was exposed to a low-temperature hydrogen plasma, similar to the plasma induced by extreme ultraviolet radiation. The experiments show that hydrogen ions are the main reducing agent. Furthermore, the addition of hydrogen radicals increases the reduction rate beyond that expected from simple flux calculations. We show that low-temperature hydrogen plasmas can be effective for reducing oxidized top surfaces. Our proof-of-concept experiments show that an in situ, EUV-generated plasma cleaning technology is feasible.

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Plasma-assisted oxide removal from ruthenium-coated EUV optics

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