Computational Approach for Epitaxial Polymorph Stabilization through Substrate Selection

Citations Over TimeTop 10% of 2016 papers

Abstract

With the ultimate goal of finding new polymorphs through targeted synthesis conditions and techniques, we outline a computational framework to select optimal substrates for epitaxial growth using first principle calculations of formation energies, elastic strain energy, and topological information. To demonstrate the approach, we study the stabilization of metastable VO2 compounds which provides a rich chemical and structural polymorph space. We find that common polymorph statistics, lattice matching, and energy above hull considerations recommends homostructural growth on TiO2 substrates, where the VO2 brookite phase would be preferentially grown on the a-c TiO2 brookite plane while the columbite and anatase structures favor the a-b plane on the respective TiO2 phases. Overall, we find that a model which incorporates a geometric unit cell area matching between the substrate and the target film as well as the resulting strain energy density of the film provide qualitative agreement with experimental observations for the heterostructural growth of known VO2 polymorphs: rutile, A and B phases. The minimal interfacial geometry matching and estimated strain energy criteria provide several suggestions for substrates and substrate-film orientations for the heterostructural growth of the hitherto hypothetical anatase, brookite, and columbite polymorphs. These criteria serve as a preliminary guidance for the experimental efforts stabilizing new materials and/or polymorphs through epitaxy. The current screening algorithm is being integrated within the Materials Project online framework and data and hence publicly available.

Related Papers

• → Photocatalytic CO₂ Reduction with H₂O on TiO₂ Nanocrystals: Comparison of Anatase, Rutile, and Brookite Polymorphs and Exploration of Surface Chemistry(2012)849 cited
• → Bicrystalline TiO2 with controllable anatase–brookite phase content for enhanced CO2 photoreduction to fuels(2013)259 cited
• → Brookite versus anatase TiO2 photocatalysts: phase transformations and photocatalytic activities(2012)253 cited
• → Brookite and anatase nanomaterial polymorphs of TiO2 synthesized from TiCl3(2017)36 cited
• Raman and UV-Vis Absorption Studies on Nanosized TiO_2Particles(2000)