Ion Beam Figuring System for Ultra-Precise Optics

Zheng Yuan; Yi Fan Dai; Xu Hui Xie; Lin Zhou

doi:10.4028/www.scientific.net/KEM.516.19

Paper Titles

Preface and Organizing Committee

Electroformed Diamond Tool Adaptable to Nanometer Grinding of Cemented Carbide
p.1

Tool Deflection Modeling in Ball-End Milling of Sculptured Surface
p.7

Multiscale Modeling Study on the Nanometric Cutting Process of CaF₂
p.13

Ion Beam Figuring System for Ultra-Precise Optics
p.19

Fabrication of PDMS Nano-Stamp by Replicating Si Nano-Moulds Fabricated by Interference Lithography
p.25

Cu-Direct Laser Drilling of Blind Via-Hole in Multi-Layer PWBs: Process Visualization Using High-Speed Camera Images
p.30

Investigation on Micro-Machining Characteristics and Phenomenon of Semiconductor Materials by Harmonics of Nd:YAG Laser
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Ultra Precision Machining of the Winston Cone Baffle for Space Observation Camera
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 516Ion Beam Figuring System for Ultra-Precise Optics

Ion Beam Figuring System for Ultra-Precise Optics

Abstract:

Ion beam figuring (IBF) is a novel technology for Ultra-precise optics. Material is removed from optic surface in atomic or molecular form by physical sputtering. Due to non-contact between the tool and the work piece, the problems involved in the conventional process are avoided, such as edge-effect and tool-wear. The ion beam figuring process is of high determinacy and high efficiency. All these properties make ion beam figuring one of the promising methods for producing mirrors of high precision with nm-rms accuracy. In this article, a new ion beam figuring system which contains doubled vacuum chambers is set up. Optics can be exchanged by a transport vehicle shuttling between the two vacuum chambers without opening the primary vacuum chamber and waiting for the ion source to cool completely, which means the efficiency can be increased greatly. A high performance processing robot contains three linear axes and two angular axes of motion, providing 5-axis ion source positioning capability with high accuracy. The angle can be up to 50° to figure very steep spherical and aspherical surfaces. Then, the beam removal function of Gaussian shape is obtained by an experimental method and it is extremely stable for a long time. Finally, two sample mirrors are figured by the ion beam figuring system: one is a fused silica flat mirror with a 100 mm diameter (90% effective aperture) and an ultra-precise flat mirror with a surface error of 0.89 nm rms, 14.7 nm PV is obtained; the other fused silica concave spherical mirror with a 100 mm aperture (90% effective aperture) and 420 mm radius of curvature is figured and a concave spherical mirror with 1 nm rms, 16.9 nm PV is obtained, which prove that the ion beam figuring system is favourable for the figuring process.

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Proceedings of Precision Engineering and Nanotechnology

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Key Engineering Materials (Volume 516)

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19-24

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.516.19

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Online since:

June 2012

Authors:

Zheng Yuan, Yi Fan Dai, Xu Hui Xie, Lin Zhou

Keywords:

Beam Removal Function, Ion Beam Figuring (IBF) System, Ultra-Precise Optics

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References

[1] J.K. Lawson, J.M. Auerbach, R.E. English, , Mark A. Henesian, John T. Hunt, Richard A. Sacks, John B. Trenholme, and Wade H. Williams, NIF optical specications – the importance of the RMS gradient, LLNL Report UCRL-JC-130032 (1998) 7-12.

DOI: 10.1117/12.354145

Google Scholar

[2] J.S. Taylor, G.E. Sommargren, D.W. Sweeney, R. M Hudyma, The Fabrication and Testing of Optics for EUV Projection Lithography. 23rd Annual International Symposium on Mircolithography, Santa Clara, California, (1998).

DOI: 10.1117/12.309619

Google Scholar

[3] P. Spano, Challenges in optics for Extremely Large Telescope instrumentation, Astron. Nachr., 327 (2006) 649-673.

Google Scholar

[4] P. Kürz, Optics for EUV Lithography. In 2nd International Workshop on EUV Lithography, 2003: Carl Zeiss.

Google Scholar

[5] L. Zhou, X.H. Xie, Y.F. Dai, C.J. Jiao, S.Y. Li, Ion beam figuring system in NUDT, In The 3rd International Symposium on Advanced Optical Manufacturing and Testing Technologies, Chengdu. SPIE, 6722 (2007) 67224A-1-67224A-6.

DOI: 10.1117/12.783658

Google Scholar

[6] C.J. Jiao, X.H. Xie, S.Y. Li, L. Zhou, Y.F. Dai, Design of Ion Beam Figuring Machine for Optics Mirrors, Key Engineering Materials, 364-366 (2008) 756-761.

DOI: 10.4028/www.scientific.net/kem.364-366.756

Google Scholar

[7] M. Fruit, A. Schindler, T. Hansel, Ion Beam Figuring of SiC Mirrors Provides Ultimate WFE Performance for any type of Telescope, In Part of the EUROPTO conference on Optical Fabrication and Testing, Berlin, Germany: SPIE (1999) 142-154.

DOI: 10.1117/12.360138

Google Scholar

[8] D. Pileri, Large optics fabrication: technology drivers and new manufacturing techniques, In Current Developments in Optical Engineering and Commercial Optics. SPIE (1989) 25-32.

DOI: 10.1117/12.962967

Google Scholar

[9] J. P. Tock, J.P. Collette, P. Gailly, D. Kampf, Figuring sequences on a super-smooth sample using ion beam technique, Part of the EUROPTO Conference on Optical Fabrication and Testing, Berlin, Germany: SPIE (1999) 132-141.

DOI: 10.1117/12.360137

Google Scholar

[10] Information on http: /www. canon. com/technology/canon tech/category/p tech. html.

Google Scholar