357 research outputs found
Emergence of topological electronic phases in elemental lithium under pressure
Lithium, a prototypical simple metal under ambient conditions, has a
surprisingly rich phase diagram under pressure, taking up several structures
with reduced symmetry, low coordination numbers, and even semiconducting
character with increasing density. Using first-principles calculations, we
demonstrate that some predicted high-pressure phases of elemental Li also host
topological electronic structures. Beginning at 80 GPa and coincident with a
transition to the Pbca phase, we find Li to be a Dirac nodal line semimetal. We
further calculate that Li retains linearly-dispersive energy bands in
subsequent predicted higher pressure phases, and that it exhibits a Lifshitz
transition between two Cmca phases at 220 GPa. The Fd-3m phase at 500 GPa forms
buckled honeycomb layers that give rise to a Dirac crossing 1 eV below the
Fermi energy. The well-isolated topological nodes near the Fermi level in these
phases result from increasing p-orbital character with density at the Fermi
level, itself a consequence of rising 1s core wavefunction overlap, and a
preference for nonsymmorphic symmetries in the crystal structures favored at
these pressures. Our results provide evidence that under pressure, bulk 3D
materials with light elements, or even pure elemental systems, can undergo
topological phase transitions hosting nontrivial topological properties near
the Fermi level with measurable consequences; and that, through pressure, we
can access these novel phases in elemental lithium.Comment: 5 pages, 5 figures, accepted for publicatio
Electric field and strain induced Rashba effect in hybrid halide perovskites
Using first principles density functional theory calculations, we show how
Rashba-type energy band splitting in the hybrid organic-inorganic halide
perovskites APbX (A=CHNH, CH(NH), Cs and X=I, Br)
can be tuned and enhanced with electric fields and anisotropic strain. In
particular, we demonstrate that the magnitude of the Rashba splitting of
tetragonal (CHNH)PbI grows with increasing macroscopic alignment of
the organic cations and electric polarization, indicating appreciable
tunability with experimentally-feasible applied fields, even at room
temperature. Further, we quantify the degree to which this effect can be tuned
via chemical substitution at the A and X sites, which alters amplitudes of
different polar distortion patterns of the inorganic PbX cage that directly
impact Rashba splitting. In addition, we predict that polar phases of CsPbI
and (CHNH)PbI with symmetry possessing considerable Rashba
splitting might be accessible at room temperature via anisotropic strain
induced by epitaxy, even in the absence of electric fields
Superlattice-induced ferroelectricity in charge-ordered LaSrFeO
Charge-order-driven ferroelectrics are an emerging class of functional
materials, distinct from conventional ferroelectrics, where electron-dominated
switching can occur at high frequency. Despite their promise, only a few
systems exhibiting this behavior have been experimentally realized thus far,
motivating the need for new materials. Here, we use density functional theory
to study the effect of artificial structuring on mixed-valence solid-solution
LaSrFeO (LSFO), a system well-studied experimentally. Our
calculations show that A-site cation (111)-layered LSFO exhibits a
ferroelectric charge-ordered phase in which inversion symmetry is broken by
changing the registry of the charge order with respect to the superlattice
layering. The phase is energetically degenerate with a ground-state
centrosymmetric phase, and the computed switching polarization is 39
C/cm, a significant value arising from electron transfer between Fe
ions. Our calculations reveal that artificial structuring of LSFO and other
mixed valence oxides with robust charge ordering in the solid solution phase
can lead to charge-order-induced ferroelectricity
First-principles study of symmetry lowering in relaxed BaTiO3/SrTiO3 superlattices
The crystal structure and local spontaneous polarization of
(BaTiO3)m/(SrTiO3)n superlattices is calculated using a first-principles
density functional theory method. The in-plane lattice constant is 1% larger
than the SrTiO3 substrate to imitate the relaxed superlattice structure and the
symmetry is lowered to monoclinic space group Cm which allows polarization to
develop along the [110] and [001] directions. The polarization component in the
[110] direction is found to develop only in the SrTiO3 layers and falls to zero
in the BaTiO3 layers, whereas the polarization in the [001] direction is
approximately uniform throughout the superlattice. These findings are
consistent with recent experimental data and first-principles results for
epitaxially strained BT and ST.Comment: 4 pages, 2 figure
Reliable energy level alignment at physisorbed molecule-metal interfaces from density functional theory.
A key quantity for molecule-metal interfaces is the energy level alignment of molecular electronic states with the metallic Fermi level. We develop and apply an efficient theoretical method, based on density functional theory (DFT) that can yield quantitatively accurate energy level alignment information for physisorbed metal-molecule interfaces. The method builds on the "DFT+Σ" approach, grounded in many-body perturbation theory, which introduces an approximate electron self-energy that corrects the level alignment obtained from conventional DFT for missing exchange and correlation effects associated with the gas-phase molecule and substrate polarization. Here, we extend the DFT+Σ approach in two important ways: first, we employ optimally tuned range-separated hybrid functionals to compute the gas-phase term, rather than rely on GW or total energy differences as in prior work; second, we use a nonclassical DFT-determined image-charge plane of the metallic surface to compute the substrate polarization term, rather than the classical DFT-derived image plane used previously. We validate this new approach by a detailed comparison with experimental and theoretical reference data for several prototypical molecule-metal interfaces, where excellent agreement with experiment is achieved: benzene on graphite (0001), and 1,4-benzenediamine, Cu-phthalocyanine, and 3,4,9,10-perylene-tetracarboxylic-dianhydride on Au(111). In particular, we show that the method correctly captures level alignment trends across chemical systems and that it retains its accuracy even for molecules for which conventional DFT suffers from severe self-interaction errors
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