6 research outputs found
Can disorder alone destroy the eg' hole pockets of NaxCoO2? A Wannier function based first-principles method for disordered systems
We investigate from first principles the proposed destruction of the
controversial eg' pockets in the Fermi surface of NaxCoO2 due to Na disorder,
by calculating its k-dependent configurational averaged spectral function
. To this end, a Wannier function based method is developed that treats
the effects of disorder beyond the mean field. Remarkable spectral broadenings
of order ~eV are found for the oxygen orbitals, possibly explaining their
absence in the experiments. Contrary to the current lore, however, the eg'
pockets remain almost perfectly coherent. The developed method is expected to
generate exciting opportunities in the study of the countless functional
materials that owe their important electronic properties to disordered dopants
BoltzWann: A code for the evaluation of thermoelectric and electronic transport properties with a maximally-localized Wannier functions basis
We present a new code to evaluate thermoelectric and electronic transport
properties of extended systems with a maximally-localized Wannier function
basis set. The semiclassical Boltzmann transport equations for the homogeneous
infinite system are solved in the constant relaxation-time approximation and
band energies and band derivatives are obtained via Wannier interpolations.
Thanks to the exponential localization of the Wannier functions obtained, very
high accuracy in the Brillouin zone integrals can be achieved with very
moderate computational costs. Moreover, the analytical expression for the band
derivatives in the Wannier basis resolves any issues that may occur when
evaluating derivatives near band crossings. The code is tested on binary and
ternary skutterudites CoSb_3 and CoGe_{3/2}S_{3/2}.Comment: 19 pages, 7 figure
Charge Ordering in Half-Doped Manganites: Weak Charge Disproportion and Leading Mechanisms
The apparent contradiction between the recently observed weak charge
disproportion and the traditional Mn/Mn picture of the
charge-orbital orders in half-doped manganites is resolved by a novel Wannier
states analysis of the LDA electronic structure. Strong electron itinerancy
in this charge-transfer system significantly delocalizes the occupied
low-energy "Mn" Wannier states such that charge leaks into the
"Mn"-sites. Furthermore, the leading mechanisms of the charge order are
quantified via our first-principles derivation of the low-energy effective
Hamiltonian. The electron-electron interaction is found to play a role as
important as the electron-lattice interaction. \ignore{A general picture of
doped holes in strongly correlated charge-transfer systems is presented and
applied to the study of charge order in half-doped manganites, using a novel
Wannier states analysis of the LDA electronic structure. While residing
primarily in the oxygen atoms, the doped holes form additional effective
orbitals at the low-energy scale, leading to an effective Mn/Mn
valence picture that enables weak charge disproportion, resolving the current
serious contradictions between the recent experimental observations of charge
distribution and traditional models. Furthermore, the leading mechanisms of the
observed charge order are quantified via our first-principles derivation of the
low-energy effective HamiltonianComment: accepted by Europhysics Letter
Orbital ordering in LaMnO: Electron-electron versus electron-lattice interactions
The relative importance of electron-lattice (e-l) and electron-electron (e-e)
interactions in ordering orbitals in LaMnO is systematically examined
within the LDA+ approximation of density functional theory. A realistic
effective Hamiltonian is derived from novel Wannier functions analysis of the
electronic structure. Surprisingly, e-l interaction ( eV) alone is
found insufficient to stabilize the orbital ordered state. On the other hand,
e-e interaction ( eV) not only induces orbital ordering, but also
greatly facilitates the Jahn-Teller distortion via enhanced localization.
Further experimental means to quantify the competition between these two
mechanisms are proposed.Comment: RevTex 4, 5 pages, 3 figures. Revision for publicatio
Electronic, vibrational and transport properties of pnictogen substituted ternary skutterudites
First principles calculations are used to investigate electronic band
structure and vibrational spectra of pnictogen substituted ternary
skutterudites. We compare the results with the prototypical binary composition
CoSb to identify the effects of substitutions on the Sb site, and evaluate
the potential of ternary skutterudites for thermoelectric applications.
Electronic transport coefficients are computed within the Boltzmann transport
formalism assuming a constant relaxation time, using a new methodology based on
maximally localized Wannier function interpolation. Our results point to a
large sensitivity of the electronic transport coefficients to carrier
concentration and to scattering mechanisms associated with the enhanced
polarity. The ionic character of the bonds is used to explain the detrimental
effect on the thermoelectric properties