Abstract
Materials that are thermodynamically stable at ultrahigh pressures (>10 GPa) often exhibit unique physical properties. However, few studies have addressed the fabrication of epitaxial thin films of ultrahigh-pressure phases. Herein, we combine epitaxial thin film growth techniques with ultrahigh-pressure synthetic methods. We demonstrate the synthesis of single-phase epitaxial thin films of an ultrahigh-pressure polymorph of TiO2, α-PbO2-type TiO2. A rutile TiO2(100) epitaxial thin film is used as a precursor, and a structural phase transition is induced at 8 GPa and 800–1000 °C. This study demonstrates a new synthetic route to obtain ultrahigh-pressure-phase materials. The fabrication of epitaxial thin film ultrahigh-pressure phases paves the way for investigating the physical properties that arise at surfaces and interfaces of materials.
Highlights
Yuki Sasahara,1,a) Koki Kanatani,1 Hiroaki Asoma,1 Masayuki Matsuhisa,1 Kazunori Nishio,1 Ryota Shimizu,1,2 Norimasa Nishiyama,3 and Taro Hitosugi1,a)
Thin films of Bi2NiMnO6,6 CaZn2N2,7 rock-salt-type ZnO,8 and diamond,9,10 which are stable under ultrahigh pressure,2,4,11 have been grown epitaxially on single crystal substrates
We developed a technique for applying ultrahigh pressure (8 GPa) to thin film samples on 5-mm single-crystal substrates, and, using a rutile TiO2(100) epitaxial thin film as a precursor, we fabricated epitaxial thin films of single-phase α-PbO2type TiO2(100)14 by inducing a structural phase transition at ultrahigh pressure
Summary
Yuki Sasahara,1,a) Koki Kanatani,1 Hiroaki Asoma,1 Masayuki Matsuhisa,1 Kazunori Nishio,1 Ryota Shimizu,1,2 Norimasa Nishiyama,3 and Taro Hitosugi1,a). Ultrahigh-pressure fabrication of single-phase α-PbO2-type TiO2 epitaxial thin films
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