1,142 research outputs found
Breakdown of the static picture of defect energetics in halide perovskites: the case of the Br vacancy in CsPbBr3
We consider the Br vacancy in CsPbBr3 as a prototype for the impact of
structural dynamics on defect energetics in halide perovskites (HaPs). Using
first-principles molecular dynamics based on density functional theory, we find
that the static picture of defect energetics breaks down; the energy of the Br
vacancy level is found to be intrinsically dynamic, oscillating by as much as 1
eV on the ps time scale at room temperature. These significant energy
fluctuations are correlated with the distance between the neighboring Pb atoms
across the vacancy and with the electrostatic potential at these Pb atomic
sites. We expect this unusually strong coupling of structural dynamics and
defect energetics to bear important implications for both experimental and
theoretical analysis of defect characteristics in HaPs. It may also hold
significant ramifications for carrier transport and defect tolerance in this
class of photovoltaic materials.Comment: 5 figures, 1 tabl
Substantial optical dielectric enhancement by volume compression in LiAsSe
Based on first-principles calculations, we predict a substantial increase in
the optical dielectric function of LiAsSe under pressure. We find that the
optical dielectric constant is enhanced threefold under volume compression.
This enhancement is mainly due to the dimerization strength reduction of the
one-dimensional (1D) As--Se chains in LiAsSe, which significantly alters
the wavefunction phase mismatch between two neighboring chains and changes the
transition intensity. By developing a tight-binding model of the interacting 1D
chains, the essential features of the low-energy electronic structure of
LiAsSe are captured. Our findings are important for understanding the
fundamental physics of LiAsSe and provide a feasible way to enhance the
material optical response that can be applied to light harvesting for energy
applications.Comment: 13 pages, 6 figure
Geometrical and electronic structures of the (5, 3) single-walled gold nanotube from first-principles calculations
The geometrical and electronic structures of the 4 {\AA} diameter perfect and
deformed (5, 3) single-walled gold nanotube (SWGT) have been studied based upon
the density-functional theory in the local-density approximation (LDA). The
calculated relaxed geometries show clearly significant deviations from those of
the ideally rolled triangular gold sheet. It is found that the different
strains have different effects on the electronic structures and density of
states of the SWGTs. And the small shear strain can reduce the binding energy
per gold atom of the deformed SWGT, which is consistent with the experimentally
observed result. Finally, we found the finite SWGT can show the
metal-semiconductor transition.Comment: 11 pages, 4 figure
First-Principles Calculation of the Bulk Photovoltaic Effect in Bismuth Ferrite
We compute the bulk photovoltaic effect (BPVE) in BiFeO3 using first-principles shift current theory, finding good agreement with experimental results. Furthermore, we reconcile apparently contradictory observations: by examining the contributions of all photovoltaic response tensor components and accounting for the geometry and ferroelectric domain structure of the experimental system, we explain the apparent lack of BPVE response in striped polydomain samples that is at odds with the significant response observed in monodomain samples. We reveal that the domain-wall-driven response in striped polydomain samples is partially mitigated by the BPVE, suggesting that enhanced efficiency could be obtained in materials with cooperative rather than antagonistic interaction between the two mechanisms
Post density functional theoretical studies of highly polar semiconductive Pb(TiNi)O solid solutions: The effects of cation arrangement on band gap
We use a combination of conventional density functional theory (DFT) and
post-DFT methods, including the local density approximation plus Hubbard
(LDA+), PBE0, and self-consistent to study the electronic properties of
Ni-substituted PbTiO (Ni-PTO) solid solutions. We find that LDA
calculations yield unreasonable band structures, especially for Ni-PTO solid
solutions that contain an uninterrupted NiO layer. Accurate treatment of
localized states in transition-metal oxides like Ni-PTO requires post-DFT
methods. -site Ni/Ti cation ordering is also investigated. The -site
cation arrangement alters the bonding between Ni and O, and therefore strongly
affects the band gap () of Ni-PTO. We predict that Ni-PTO solid
solutions should have a direct band gap in the visible light energy range, with
polarization similar to the parent PbTiO. This combination of properties
make Ni-PTO solid solutions promising candidate materials for solar energy
conversion devices.Comment: 19 pages, 6 figure
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