"High Precision Detection of Change in Intermediate Range Order of Amor" by K. Prasai, J. Jiang et al.

Physics & Astronomy Open Access Publications

Title

High Precision Detection of Change in Intermediate Range Order of Amorphous Zirconia-Doped Tantala Thin Films Due to Annealing

Authors

K. Prasai, Ginzton Laboratory
J. Jiang, University of Florida
A. Mishkin, University of Florida
B. Shyam, University of Dayton
S. Angelova, University of Strathclyde
R. Birney, University of Strathclyde
D. A. Drabold, Ohio University
M. Fazio, Colorado State University
E. K. Gustafson, California Institute of Technology
G. Harry, American University
S. Hoback, American University
J. Hough, University of Glasgow
C. Lévesque, University of Montreal
I. Maclaren, University of Glasgow
A. Markosyan, Ginzton Laboratory
I. W. Martin, University of Glasgow
C. S. Menoni, Colorado State University
P. G. Murray, University of Glasgow
S. Penn, Hobart and William Smith Colleges
S. Reid, University of Strathclyde
R. Robie, University of Glasgow
S. Rowan, University of Glasgow
F. Schiettekatte, University of Montreal
R. Shink, University of Montreal
A. Turner, University of Glasgow
G. Vajente, California Institute of Technology
H. P. Cheng, University of Florida
M. M. Fejer, Ginzton Laboratory
A. Mehta, SLAC National Accelerator Laboratory
R. Bassiri, Ginzton Laboratory

Document Type

Article

Publication Date

7-23-2019

Abstract

© 2019 American Physical Society. Understanding the local atomic order in amorphous thin film coatings and how it relates to macroscopic performance factors, such as mechanical loss, provides an important path towards enabling the accelerated discovery and development of improved coatings. High precision x-ray scattering measurements of thin films of amorphous zirconia-doped tantala (ZrO2-Ta2O5) show systematic changes in intermediate range order (IRO) as a function of postdeposition heat treatment (annealing). Atomic modeling captures and explains these changes, and shows that the material has building blocks of metal-centered polyhedra and the effect of annealing is to alter the connections between the polyhedra. The observed changes in IRO are associated with a shift in the ratio of corner-sharing to edge-sharing polyhedra. These changes correlate with changes in mechanical loss upon annealing, and suggest that the mechanical loss can be reduced by developing a material with a designed ratio of corner-sharing to edge-sharing polyhedra.

Recommended Citation

Prasai, K.; Jiang, J.; Mishkin, A.; Shyam, B.; Angelova, S.; Birney, R.; Drabold, D. A.; Fazio, M.; Gustafson, E. K.; Harry, G.; Hoback, S.; Hough, J.; Lévesque, C.; Maclaren, I.; Markosyan, A.; Martin, I. W.; Menoni, C. S.; Murray, P. G.; Penn, S.; Reid, S.; Robie, R.; Rowan, S.; Schiettekatte, F.; Shink, R.; Turner, A.; Vajente, G.; Cheng, H. P.; Fejer, M. M.; Mehta, A.; and Bassiri, R., "High Precision Detection of Change in Intermediate Range Order of Amorphous Zirconia-Doped Tantala Thin Films Due to Annealing" (2019). Physics & Astronomy Open Access Publications. 25.
https://ohioopen.library.ohio.edu/physics-astronomy-oapub/25

Link to Full Text

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