Atomic Oxygen Resistant Polysiloxane Coatings for Low Earth Orbit Space Structures

G.N. Arjun; T.L. Lincy; T.S. Sajitha; S. Bhuvaneshwari; Thomas Deepthi; Deepa Devapal

doi:10.4028/www.scientific.net/MSF.830-831.699

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HomeMaterials Science ForumMaterials Science Forum Vols. 830-831Atomic Oxygen Resistant Polysiloxane Coatings for...

Atomic Oxygen Resistant Polysiloxane Coatings for Low Earth Orbit Space Structures

Abstract:

Polysiloxane resin copolymer was synthesized through acid catalyzed hydrolysis of methyl triethoxysilane (MTEOS) and diethoxytetramethyldisiloxane (DEOTMDS). The effect of reaction time on the properties of the polymer was studied and this copolymer was characterized by GPC, ²⁹Si NMR, IR, TGA, viscosity, refractive index, specific gravity and solid content. ²⁹Si NMR and IR showed characteristic signals of Si-O-Si linkage which confirmed the formation of the polymer. GPC and solid content analysis showed an increasing trend in molecular weight with reaction time. Thermo gravimetric analysis showed that the polymer was thermally stable upto ≈ 260°C and all the polymers gave a ceramic residue in the range of 77-80% at 900°C. Siloxane prepared inhouse and methyl phenyl silsequioxane (control) were used as coating materials and atomic oxygen (AO) resistance was evaluated on Al-Kapton, carbon polyimide composite and glass polyimide composite. The mass loss and surface morphology of the coated samples were measured at different time intervals. It is observed that mass loss of polysiloxane coated samples was very less, compared to coated control samples. The morphology of all the samples were studied using FESEM. Erosion kinetics and surface morphology investigation indicate that the polysiloxane coating possesses excellent AO resistance, and displays better cracking resistance on AO exposure.

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Periodical:

Materials Science Forum (Volumes 830-831)

Pages:

699-702

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.830-831.699

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Online since:

September 2015

Authors:

G.N. Arjun, T.L. Lincy, T.S. Sajitha, S. Bhuvaneshwari, Thomas Deepthi, Deepa Devapal*

Keywords:

Acid Catalyzed Hydrolysis, Atomic Oxygen Resistance, Low Earth Orbit, Polysiloxane

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References

[1] NASA/SDIO Space Environmental Effects on Materials Workshop Held in Hampton, Virginia on June 28-July 1, 1988. Part 2.

Google Scholar

[2] G.A. Dries, and S. S Tompkins, Effects of Thermal Cycling on Thermal Expansion and Mechanical Properties of Several Graphite-Reinforced Aluminum Metal-Matrix Composites. NASA TP-2701, July (1987).

Google Scholar

[3] W. Slemp, S. Tompkins, D. Bowles, and L. Teichman, Response of composite materials to the space station orbit environment (1988).

DOI: 10.2514/6.1988-2476

Google Scholar

[4] G.G. Reibaldi, Thermomechanical behaviour of CFRP tubes for space structures. Acta Astronautica 12 (1985) 323–333.

DOI: 10.1016/0094-5765(85)90066-9

Google Scholar

[5] V.F. Janas, Thermal-expansion hysteresis in graphite/glass composites. SAMPE Q. (United States) 19 (1988).

Google Scholar

[6] G. Allegri, S. Corradi, M. Marchetti, and V. Milinchuck, V. Atomic oxygen degradation of polymeric thin films in low earth orbit. AIAA journal 41 (2003) 1525–1534.

DOI: 10.2514/2.2103

Google Scholar

[7] M.R. Reddy, Effect of low earth orbit atomic oxygen on spacecraft materials. Journal of Materials Science 30 (1995) 281–307.

DOI: 10.1007/bf00354389

Google Scholar

[8] S. Packirisamy, D. Schwam, and M.H. Litt, Atomic oxygen resistant coatings for low earth orbit space structures. Journal of materials science 30 (1995) 308–320.

DOI: 10.1007/bf00354390

Google Scholar

[9] D. Deepa, S. Packirisamy, M.K. Raji, and K.N. Ninan, Atomic oxygen resistant coatings from Poly (tetramethyldisilylene-co-styrene). Journal of Applied polymer science 94 (2004) 2368-2375.

DOI: 10.1002/app.21148

Google Scholar

[10] S. Packirisamy, G. Abraham, D. Devapal, R. Ramasamy, K. N Ninan, and K.S. Sastry, Indian Pat. Appl. No. 1002/CHE/(2005).

Google Scholar

[11] S. Packirisamy, Decaborane (14)-based polymers. Prog Polym Sci 21 (1996) 707-773.

Google Scholar

[12] D. Deepa, S. Packirisamy, C.P. Reghunadhan Nair, and K.N. Ninan, Phosphazene-based polymers as atomic oxygen resistant materials. Journal of materials science 41 (2006) 5764-5766.

DOI: 10.1007/s10853-006-0109-5

Google Scholar