117 research outputs found
A polynomial Ansatz for Norm-conserving Pseudopotentials
We show that efficient norm-conserving pseudopotentials for electronic
structure calculations can be obtained from a polynomial Ansatz for the
potential. Our pseudopotential is a polynomial of degree ten in the radial
variable and fulfills the same smoothness conditions imposed by the
Troullier-Martins method [Phys. Rev. B 43, 1993 (1991)] where pseudopotentials
are represented by a polynomial of degree twenty-two. We compare our method to
the Troullier-Martins approach in electronic structure calculations for diamond
and iron in the bcc structure and find that the two methods perform equally
well in calculations of the total energy. However, first and second derivatives
of the total energy with respect to atomic coordinates converge significantly
faster with the plane wave cutoff if the standard Troullier-Martins potentials
are replaced by the pseudopotentials introduced here.Comment: 7 pages, 3 figure
Thermoelastic properties of -iron from first-principles
We calculate the thermomechanical properties of -iron, and in
particular its isothermal and adiabatic elastic constants, using
first-principles total-energy and lattice-dynamics calculations, minimizing the
quasi-harmonic vibrational free energy under finite strain deformations.
Particular care is made in the fitting procedure for the static and
temperature-dependent contributions to the free energy, in discussing error
propagation for the two contributions separately, and in the verification and
validation of pseudopotential and all-electron calculations. We find that the
zero-temperature mechanical properties are sensitive to the details of the
calculation strategy employed, and common semi-local exchange-correlation
functionals provide only fair to good agreement with experimental elastic
constants, while their temperature dependence is in excellent agreement with
experiments in a wide range of temperature almost up to the Curie transition.Comment: Accepted as regular article in Phys. Rev.
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