Award Date
12-1-2024
Degree Type
Dissertation
Degree Name
Doctor of Philosophy (PhD)
Department
Physics and Astronomy
First Committee Member
Ashkan Salamat
Second Committee Member
Keith V. Lawler
Third Committee Member
Andrew Cornelius
Fourth Committee Member
Alexander Barzilov
Number of Pages
131
Abstract
Exploration and fine-tuning of the energy landscape of materials can be accessed by means of changes in material density, a key principle of high pressure research. Density-driven changes impact variations in oxidation states and coordination numbers for the element constituents of a compound. Pressure-induced modification of intrinsic density can promote the formation of new materials, variations in physical properties, and transformations in crystallographic symmetry. With this as our foundation, we focus on ruthenium binary compounds - altering the anion species to change electronegativity while probing pressure and temperature effects. This led us to the present study of ruthenium oxide RuO2, nitride RuN2, and sulfide RuS2, wherein we measure the pressure response of physical properties and characterize corresponding crystal structures. We report the discovery of multiple new high pressure phases of RuO2, the first high pressure experiments on RuS2, and the formation of RuN2 while seeking to explore new materials through high-pressure, high-temperature synthesis. These works utilized a combination of high pressure synchrotron x-ray diffraction, in-house Raman spectroscopy, diamond anvil cell electrical transport, laser heating, and cryostat techniques, with additional support and insight from DFT simulations.
Keywords
electrical transport measurements; high pressure; Raman spectrocopy; ruthenium binary compounds; x-ray diffraction
Disciplines
Engineering Science and Materials | Materials Science and Engineering | Physics
File Format
File Size
9400 KB
Degree Grantor
University of Nevada, Las Vegas
Language
English
Repository Citation
White, Melanie, "Density-Driven Investigations of Ruthenium Binary Compounds RuX2 (X = O, S, N)" (2024). UNLV Theses, Dissertations, Professional Papers, and Capstones. 5214.
https://digitalscholarship.unlv.edu/thesesdissertations/5214
Rights
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Included in
Engineering Science and Materials Commons, Materials Science and Engineering Commons, Physics Commons
