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In situ XRPD study of the ambient-pressure synthesis of nonstoichiometric Ag3O from Ag–Ag2O thin films: Phase abundance, unit-cell parameters, and c/a as a function of temperature and time

Published online by Cambridge University Press:  28 October 2020

Paul J. Schields Open the ORCID record for Paul J. Schields [Opens in a new window] ,
Nicholas Dunwoody ,
David Field  and
Zachary Wilson
Paul J. Schields*
Affiliation:
Albany Molecular Research Inc., West Lafayette, IN47906, USA
Nicholas Dunwoody
Affiliation:
Tetraphase Pharmaceuticals, Inc., Watertown, MA02472, USA
David Field
Affiliation:
Calgary, AB, CanadaT2M 0E
Zachary Wilson
Affiliation:
Groton, MA01450, USA
*
a)Author to whom correspondence should be addressed. Electronic mail: [email protected]
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Abstract

Ag3O was synthesized by jet-milling magnetron-sputtered Ag–Ag2O thin films. Heating the jet-milled powders in air and N2 from 40 to 148 °C at ambient pressure produced Ag3O-rich powders. The phase composition and unit-cell parameters of the jet-milled powders were measured as a function of temperature with in situ X-ray powder diffraction experiments from −186 to 293 °C. Ag3O was also produced by ball milling and sonicating jet-milled films at ambient conditions. The phase composition, unit-cell parameters, and thermal-reaction rates indicate nonstoichiometric Ag3O was produced from the reaction of metastable, nonstoichiometric Ag2O (cuprite structure) and ccp Ag. The thermal expansion of Ag3O is anisotropic; below 25 °C, the a-axis expansion is about twice the c-axis expansion resulting in a negative slope of c/a(T). The reversal of the sign of c/a(T) near 25 °C is dramatic. The thermal reaction is arrested when the temperature is rapidly increased from ambient to 130 °C. Ag3O is metastable and decreases its unit-cell volume during kinetic decomposition to Ag when heated above ambient temperature in air and nitrogen. The relative volume expansion of Ag3O is about 80% less than Ag at room temperature and below. The suite of nonstoichiometric Ag3O produced by heating displays a linear relation between c/a and unit-cell volume at room temperature. The c/a and unit-cell volume of a hydrothermally grown Ag3O single crystal reported in a published structure determination was the Ag-rich, low-volume end member of the linear series. The c/a and unit-cell volume are sensitive indicators of the oxygen content and state of disorder.

Keywords

Ag3OAg2OAgin situ thermal reactionthermal expansionnonstoichiometryXRPD
Type
Technical Article
Information
Powder Diffraction , Volume 35 , Issue 4 , December 2020 , pp. 247 - 261
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Copyright
Copyright © 2020 International Centre for Diffraction Data

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References

Allen, J. A. (1960). “Thermal decomposition of silver (I) oxide,” Aust. J. Chem. 13, 431442.CrossRefGoogle Scholar
Banerjee, S. and Mukhopadhyay, P. (2007) “Interstitial ordering,” in Phase Transformation: Examples from Titanium and Zirconium Alloys, edited by R. W. Cahn (Elsevier Science, Amsterdam, The Netherlands), Vol. 12, pp. Chapter 8, pp. 719781.CrossRefGoogle Scholar
Beesk, W., Jones, P. G., Rumpel, H., Schwarzmann, E., and Sheldrick, G. M. (1981). “X-ray crystal structure of Ag6O2,” J. Chem. Soc., Chem. Commun, 664665.CrossRefGoogle Scholar
Birkenberg, B. and Schwarzmann, E. (1974). “Zuchtung von Ag2O-Kristallen unter hydrothermalen Bedingungen,” Z. Naturforsch. 29b, 113114.CrossRefGoogle Scholar
Bruker-AXS (2009). TOPAS V4.2, “General profile and structure analysis software for powder diffraction data,” User's Manual, Bruker-AXS 5465 Karlsruhe, Germany.Google Scholar
Culbertson, W. J. Jr., (1964). “Investigation and design of a regenerable silver oxide system for carbon dioxide control,” Denver Research Institute, AMRL-TR-64-119.CrossRefGoogle Scholar
Faivre, R. (1940). “Formation de solutions d'insertion au cours de la dissociation de l'oxyde d'argent,” Compt. Rend. Hebd. Seances Acad. Sci. 210, 398400.Google Scholar
Hirabayashi, M., Yamaguchi, S., and Arai, T. (1973). "Superstructure and order–disorder transformation of interstitial oxygen in Hafnium,” J. Phys. Soc. Japan 35(2), 473481.CrossRefGoogle Scholar
Hölzer, G., Fritsch, M., Deutsch, M., Härtwig, J., and Förster, E. (1997). “1,2 and βK 1,3 X-ray emission lines of the 3d transition metals,” Phys. Rev. A 56, 45544568.CrossRefGoogle Scholar
Iwanaga, H., Kunishige, A., and Takeuchi, S. (2000). “Anisotropic thermal expansion in wurtzite-type crystal,” J. Mat. Sci. 35, 24512454.CrossRefGoogle Scholar
Kabalikina, S. S., Popova, S. V., Serebryanaya, N. R., and Vereshchagin, L. F. (1963). “A new modification of Ag2O with a layer structure,” Sov. Phys. - Dokl. 8, 972.Google Scholar
Kato, A. and Anju, Y. (1972). “Expansion of Ag2O lattice by annealing,” J. Am. Ceram. Soc. 55, 2528.CrossRefGoogle Scholar
Kern, A., Coelho, A. A., and Cheary, R. W. (2004). “Convolution based profile fitting,” in Diffraction Analysis of the Microstructure of Materials, edited by Mittemeijer, E. J. and Scardi, P., Materials Science (Springer), pp. 1750.CrossRefGoogle Scholar
Kosova, D. A., Emelina, A., and Bykov, M. (2014). “Phase transitions of some sulfur-containing ammonium salts,” Thermochim. Acta 595, 6166.CrossRefGoogle Scholar
Lutterotti, L., Matthies, S., and Wenk, H.R. (1999). “MAUD (Materials analysis Using Diffraction): a user friendly Java program for Rietveld Texture Analysis and more,” in Proceeding of the Twelfth International Conference on Textures of Materials (NRC Research Press, Ottawa, Canada), Vol. 1, p. 1599.Google Scholar
Norby, P., Dinnebier, R., and Fitch, A. N. (2002). “Decomposition of silver carbonate; the crystal structure of two high-temperature modifications of Ag2CO3,” Inorg. Chem. 41, 36283637.CrossRefGoogle Scholar
Nordman, C. E. and Schmitkons, D. L. (1965). “Phase transition and crystal structures of adamantane,” Acta Cryst. 18, 764767.CrossRefGoogle Scholar
Öztürk, H., Yan, H., Hill, J. P., and Noyan, I. C. (2015). “Correlating sampling and intensity statistics in nanoparticle diffraction experiments,” J. Appl. Cryst. 48, 12121227.CrossRefGoogle Scholar
Pawley, G. S. (1981). “Unit-cell refinement from powder diffraction scans,” J. Appl. Cryst. 14, 357361.CrossRefGoogle Scholar
Schields, P. J., Dunwoody, N., Mamak, M., Gendron, C., and Bates, S. (2007). “Comparison of simulated and experimental XRPD patterns of silver with twin faults using MAUD and DIFFaX,” Adv. X-ray Anal. 51, 162168.Google Scholar
Schlemper, E. O. and Hamilton, W. C. (1966). “Neutron-diffraction study of the structures of ferroelectric and paraelectric ammonium sulfate,” J. Chem. Phys. 44, 44984509.CrossRefGoogle Scholar
Suh, I., Ohta, H., and Waseda, Y. (1988). “High-temperature thermal expansion of six metallic elements measured by dilation method and X-ray diffraction,” J. Mat. Sci. 23, 757760.10.1007/BF01174717CrossRefGoogle Scholar
Taylor, P. L., Omotoso, O., Wiskel, J. B., Mitlin, D., and Burrell, R. E. (2005). “Impact of heat on nanocrystalline silver dressings. Part II: Physical properties,” Biomaterials 26, 72307240.CrossRefGoogle ScholarPubMed
Tiano, W., Dapiaggi, M., and Artioli, G. (2003). “Thermal expansion in cuprite-type structures from 10 K to decomposition temperature: Cu2O and Ag2O,” J. App. Cryst. 36, 14611463.CrossRefGoogle Scholar
van Ekeren, P. J., van Genderen, A. C. G., and van den Berg, G. J. K. (2006). “Redetermination of the thermodynamic properties of the solid-solid transition of adamantane by adiabatic calorimetry to investigate the suitability as a reference material for low-temperature DSC-calibration,” Thermochim. Acta 446, 3335.CrossRefGoogle Scholar
Wei, W., Mao, X., Ortiz, L. A., and Sadoway, D. R. (2011). “Oriented silver oxide nanostructures synthesized through a template-free electrochemical route,” J. Mat. Chem. 21, 432438.CrossRefGoogle Scholar
Williams, A. (1989). “Neutron powder diffraction study of silver subfluoride,” J. Phys. Condens. Matter 1, 25692574.CrossRefGoogle Scholar
Yoder-Short, D. (1993). “On a small error in SRM640, SRM640a and SRM640b lattice parameters,” J. Appl. Cryst. 26, 272276.CrossRefGoogle Scholar
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