Temperature-Driven Twin Structure Formation and Electronic Structure of Epitaxially Grown Mg3Sb2 Films on Mismatched Substrates

• Published in: Nanomaterials (Basel, Switzerland) Vol. 12; no. 24; p. 4429
• Main Authors: Xie, Sen, Ouyang, Yujie, Liu, Wei, Yan, Fan, Luo, Jiangfan, Li, Xianda, Wang, Ziyu, Liu, Yong, Tang, Xinfeng
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 12.12.2022; MDPI
• Subjects: Chemical bonds; Controllability; Crystal structure; Electronic structure; Epitaxial growth; Fermi level; Film growth; Island growth; Mass transfer; Metalloids; Mg3Sb2 films; Molecular beam epitaxy; Optimization; Photoelectric emission; Room temperature; Sapphire; Solid solutions; Spectroscopy; Spectrum analysis; Strain relaxation; Substrates; Thermoelectric materials; Topology; twin structure; Germany
• ISSN: 2079-4991; 2079-4991
• DOI: 10.3390/nano12244429

Mg3Sb2-based compounds are one type of important room-temperature thermoelectric materials and the appropriate candidate of type-II nodal line semimetals. In Mg3Sb2-based films, compelling research topics such as dimensionality reduction and topological states rely on the controllable preparation of films with high crystallinity, which remains a big challenge. In this work, high quality Mg3Sb2 films are successfully grown on mismatched substrates of sapphire (000l), while the temperature-driven twin structure evolution and characteristics of the electronic structure are revealed in the as-grown Mg3Sb2 films by in situ and ex situ measurements. The transition of layer-to-island growth of Mg3Sb2 films is kinetically controlled by increasing the substrate temperature (Tsub), which is accompanied with the rational manipulation of twin structure and epitaxial strains. Twin-free structure could be acquired in the Mg3Sb2 film grown at a low Tsub of 573 K, while the formation of twin structure is significantly promoted by elevating the Tsub and annealing, in close relation to the processes of strain relaxation and enhanced mass transfer. Measurements of scanning tunneling spectroscopy (STS) and angle-resolved photoemission spectroscopy (ARPES) elucidate the intrinsic p-type conduction of Mg3Sb2 films and a bulk band gap of ~0.89 eV, and a prominent Fermi level downshift of ~0.2 eV could be achieved by controlling the film growth parameters. As elucidated in this work, the effective manipulation of the epitaxial strains, twin structure and Fermi level is instructive and beneficial for the further exploration and optimization of thermoelectric and topological properties of Mg3Sb2-based films.