Published September 10, 2021 | Published + Supplemental Material + Accepted Version

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Enhanced medium-range order in vapor-deposited germania glasses at elevated temperatures

Creators: Yang, Le; Vajente, Gabriele; Fazio, Mariana; Ananyeva, Alena; Billingsley, Garilynn; Markosyan, Ashot; Bassiri, Riccardo; Prasai, Kiran; Fejer, Martin M.; Chicoine, Martin; Schiettekatte, François; Menoni, Carmen S.

Abstract

Glasses are nonequilibrium solids with properties highly dependent on their method of preparation. In vapor-deposited molecular glasses, structural organization could be readily tuned with deposition rate and substrate temperature. Here, we show that the atomic arrangement of strong network-forming GeO₂ glass is modified at medium range (<2 nm) through vapor deposition at elevated temperatures. Raman spectral signatures distinctively show that the population of six-membered GeO₄ rings increases at elevated substrate temperatures. Deposition near the glass transition temperature is more efficient than postgrowth annealing in modifying atomic structure at medium range. The enhanced medium-range organization correlates with reduction of the room temperature internal friction. Identifying the microscopic origin of room temperature internal friction in amorphous oxides is paramount to design the next-generation interference coatings for mirrors of the end test masses of gravitational wave interferometers, in which the room temperature internal friction is a main source of noise limiting their sensitivity.

Additional Information

© 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC). Submitted 2 March 2021; Accepted 21 July 2021; Published 10 September 2021. The Raman scattering was performed at the Raman Microspectroscopy Laboratory in the Department of Geological Science at the University of Colorado-Boulder. Funding: This study was supported by the National Science Foundation (NSF) LIGO program through grant nos. 1710957 (L.Y. and C.S.M.) and 1708010 (M.F. and C.S.M.), NSF awards PHY-1707866 and PHY-1708175 (A.M., R.B., and M.M.F.), GBMF grant no. 6793 (A.M., K.P., R.B., and M.M.F.), FRQNT through the Regroupement québécois sur les matériaux de pointe (RQMP), and Natural Sciences and Engineering Research Council of Canada (M.C. and F.S.). Author contributions: L.Y., M.F., and C.S.M. conceived the experiment. L.Y. and M.F. performed the thin-film deposition and material spectroscopy analysis. G.V., A.A., and G.B. performed the room temperature internal friction measurements. A.M., R.B., K.P., and M.M.F. contributed to the XRD measurements. M.C. and F.S. contributed to the RBS measurements. All authors contributed to the preparation of the manuscript. The authors declare that they have no competing interests. Data and materials availability: All data needed to evaluate the conclusions in the paper are present in the paper and/or the Supplementary Materials.

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Published - sciadv.abh1117.pdf

Accepted Version - 2102.08526.pdf

Supplemental Material - sciadv.abh1117_sm.pdf

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