Environmental adaptability tests for low temperature bonding interface of quartz glass

Li Pan; Liu Yuanzheng; Lei Xing; Li Jun; Wang Jiliang

Low temperature bonding for quartz glass as a reliable solid connection technology has received extensive attention in developed countries in Europe and America, and has been widely used in many fields such as aerospace, basic research, strong laser etc.. Low temperature bonding based on hydroxide-catalyzed hydration/dehydration at the glass surface is a low temperature bonding method with high breaking strength, high precision and high reliability by forming three-dimensional silicate networks at the interface. The physical principle and the basic process of low temperature bonding was demonstrated and the low temperature bonding for quartz glass was realized too. The results of the bonding interface of environmental adaptability test show that, compared with conventional optical contact method, low temperature bonding is superior in bonding strength and adaptability in temperature shock environment and water environment, while low temperature bonding matches optical contact in uniformity, precision, transparency, vacuum seal and adaptability in regular temperature environment and vibration environment.

1. Flight Automatic Control Research Institute,Xi'an 710065,China

Received Date: 2014-04-10

Rev Recd Date: 2014-05-18

Publish Date: 2014-12-25

Key words:

Abstract: Low temperature bonding for quartz glass as a reliable solid connection technology has received extensive attention in developed countries in Europe and America, and has been widely used in many fields such as aerospace, basic research, strong laser etc.. Low temperature bonding based on hydroxide-catalyzed hydration/dehydration at the glass surface is a low temperature bonding method with high breaking strength, high precision and high reliability by forming three-dimensional silicate networks at the interface. The physical principle and the basic process of low temperature bonding was demonstrated and the low temperature bonding for quartz glass was realized too. The results of the bonding interface of environmental adaptability test show that, compared with conventional optical contact method, low temperature bonding is superior in bonding strength and adaptability in temperature shock environment and water environment, while low temperature bonding matches optical contact in uniformity, precision, transparency, vacuum seal and adaptability in regular temperature environment and vibration environment.

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Reference (27)

[1]	Rowan S, Twyford S M, Hough J, et al. Mechanical losses associated with the technique of hydroxide-catalysis bonding of fused silica [J]. Physics Letters A, 1998, 246(6): 471-478.
[2]
[3]
[4]	Gwo D H. Ultra-precision bonding for cryogenic quartz glass optics [C]//SPIE Conference on Cryogenic Optical Systems and Instruments VIII, 1998: 136-142.
[5]	Elliffe E J, Bogenstahl J, Deshpande A, et al. Hydroxide-catalysis bonding for stable optical systems for space [J]. Classical and Quantum Gravity, 2005, 22(10): S257-S267.
[6]
[7]	Preston A, Cruz R, Thorpe J I, et al. Dimensional stability of hexoloy SA silicon carbide and zerodur glass using hydroxide-catalysis bonding for optical systems in space[C]//SPIE on Optomechanical Technologies for Astronomy, 2006: 6273.
[8]
[9]
[10]	Beveridge N L. Characterisation of silicon-silicon hydroxide catalysis bonds for future gravitational wave detectors [D]. UK: University of Glasgow, 2012.
[11]
[12]	Dari A, Travasso F, Vocca H, et al. Breaking strength tests on silicon and sapphire bondings for gravitational wave detectors[J]. Classical and Quantum Gravity, 2010, 27(4): 045010.
[13]
[14]	Sinha S, Urbanek K E, Krzywicki A, et al. Investigation of the suitability of silicate bonding for facet termination in active fiber devices [J]. Optics Express, 2007, 15 (20): 13003-13022.
[15]	Strzelecki M T, Magida M, O'Malley R, et al. Low temperature bonding of light-weighted mirrors [C]//SPIE on Optical Materials and Structures Technologies, 2003: 50-55.
[16]
[17]
[18]	Veggel A A, van den Endeb D, Bogenstahl J, et al. Hydroxide catalysis bonding of silicon carbide [J]. Journal of the European Ceramic Society, 2008, 28: 303-310.
[19]	Brinkmann M, Hayden J S, Okano Y. Glass modification techniques for photonic devices [C]//SPIE on Optical Materials and Structures Technologies, 2003: 96-102.
[20]
[21]
[22]	Veggel A A, van den Endeb D, Bogenstahl J, et al. Hydroxide catalysis bonding of silicon carbide[J]. Journal of the European Ceramic Society, 2008, 28(1): 303-310.
[23]	NASA's Jet Propulsion Laboratory. Hydroxide-assisted bonding of ultra-low-expansion glass [R]. USA: NASA, 2008: 7.
[24]
[25]
[26]	Marshall Space Flight Center. Bonding by hydroxide-catalyzed hydration and dehydration [R]. USA: NASA, 2008: 17-18.
[27]	Mackenzie K, Brown I, Ranchod P, et al. Silicate bonding of inorganic materials Part 1. Chemical reactions in sodium silicate at room temperature [J]. Journal of Materials Science, 1991, 26(3): 763-768.

Environmental adaptability tests for low temperature bonding interface of quartz glass

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