Abstract
Two-dimensional titanium trisulfide (TiS3) attracts much attention due to its high carrier mobilities and anisotropic physical properties. In this study, based on the ab-initio method, the vibrational, carrier transport and excitonic properties for TiS3 monolayer are investigated in detail. The results show that highly anisotropic structure of monolayer TiS3 leads to its anisotropic physical properties. The hole mobilities are larger than electron mobilities, which can be further enhanced by strain engineering. A strong absorption peak at 0.59 eV for light polarization along b direction is observed within the quasi-particle bandgap, which is 15 times larger than that at 0.98 eV for light polarization along a direction. The absorption peaks are contributed dominantly by bright excitons whose binding energies are 0.43 eV and 0.82 eV along a and b directions, both of which are delocalized Wannier-Mott types. The ultrahigh and flexibly strain-engineering transport properties and the significant excitonic effects of anisotropic TiS3 monolayer make possible applications in flexible electronic and optoelectronic devices.
Published Version
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