Paweł Lenarczyk - Academia.edu (original) (raw)
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Université Sorbonne Paris Nord / Sorbonne Paris Nord University
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Papers by Paweł Lenarczyk
Localized Wannier functions provide an efficient and intuitive framework to compute electric pola... more Localized Wannier functions provide an efficient and intuitive framework to compute electric polarization from first-principles. They can also be used to represent the electronic systems at fixed electric field and to determine dielectric properties of insulating materials. Here we develop a Wannier-function-based formalism to perform first-principles calculations at fixed polarization. Such an approach allows to extract the polarization-energy landscape of a crystal and thus supports the theoretical investigation of polar materials. To facilitate the calculations, we implement a quasi-Newton method that simultaneously relaxes the internal coordinates and adjusts the electric field in crystals at fixed polarization. The method is applied to study the ferroelectric behavior of BaTiO_3 and PbTiO_3 in tetragonal phases. The physical processes driving the ferroelectricity of both compounds are examined thanks to the localized orbital picture offered by Wannier functions. Hence, changes ...
We describe a method to calculate the electronic properties of an insulator under an applied elec... more We describe a method to calculate the electronic properties of an insulator under an applied electric field. It is based on the minimization of an electric enthalpy functional with respect to the orbitals, which behave as Wannier functions under crystal translations, but are not necessarily orthogonal. This paper extends the approach of Nunes and Vanderbilt (NV) [Phys. Rev. Lett. 73, 712 (1994)], who demonstrated that a Wannier function representation can be used to study insulating crystals in the presence of a finite electric field. According to a study by Fernandez et al. [Phys. Rev. B. 58, R7480 (1998)], first-principles implementations of the NV approach suffer from the impact of the localization constraint on the orthogonal wave functions, what affects the accuracy of the physical results. We show that because non-orthogonal generalized Wannier functions can be more localized than their orthogonal counterparts, the error due to localization constraints is reduced, thus improvi...
Localized Wannier functions provide an efficient and intuitive framework to compute electric pola... more Localized Wannier functions provide an efficient and intuitive framework to compute electric polarization from first-principles. They can also be used to represent the electronic systems at fixed electric field and to determine dielectric properties of insulating materials. Here we develop a Wannier-function-based formalism to perform first-principles calculations at fixed polarization. Such an approach allows to extract the polarization-energy landscape of a crystal and thus supports the theoretical investigation of polar materials. To facilitate the calculations, we implement a quasi-Newton method that simultaneously relaxes the internal coordinates and adjusts the electric field in crystals at fixed polarization. The method is applied to study the ferroelectric behavior of mathrmBaTiO_3\mathrm{BaTiO_3}mathrmBaTiO3 and mathrmPbTiO3\mathrm{PbTiO_3}mathrmPbTiO_3 in tetragonal phases. The physical processes driving the ferroelectricity of both compounds are examined thanks to the localized orbital picture offered by Wannier func...
Localized Wannier functions provide an efficient and intuitive framework to compute electric pola... more Localized Wannier functions provide an efficient and intuitive framework to compute electric polarization from first-principles. They can also be used to represent the electronic systems at fixed electric field and to determine dielectric properties of insulating materials. Here we develop a Wannier-function-based formalism to perform first-principles calculations at fixed polarization. Such an approach allows to extract the polarization-energy landscape of a crystal and thus supports the theoretical investigation of polar materials. To facilitate the calculations, we implement a quasi-Newton method that simultaneously relaxes the internal coordinates and adjusts the electric field in crystals at fixed polarization. The method is applied to study the ferroelectric behavior of BaTiO_3 and PbTiO_3 in tetragonal phases. The physical processes driving the ferroelectricity of both compounds are examined thanks to the localized orbital picture offered by Wannier functions. Hence, changes ...
We describe a method to calculate the electronic properties of an insulator under an applied elec... more We describe a method to calculate the electronic properties of an insulator under an applied electric field. It is based on the minimization of an electric enthalpy functional with respect to the orbitals, which behave as Wannier functions under crystal translations, but are not necessarily orthogonal. This paper extends the approach of Nunes and Vanderbilt (NV) [Phys. Rev. Lett. 73, 712 (1994)], who demonstrated that a Wannier function representation can be used to study insulating crystals in the presence of a finite electric field. According to a study by Fernandez et al. [Phys. Rev. B. 58, R7480 (1998)], first-principles implementations of the NV approach suffer from the impact of the localization constraint on the orthogonal wave functions, what affects the accuracy of the physical results. We show that because non-orthogonal generalized Wannier functions can be more localized than their orthogonal counterparts, the error due to localization constraints is reduced, thus improvi...
Localized Wannier functions provide an efficient and intuitive framework to compute electric pola... more Localized Wannier functions provide an efficient and intuitive framework to compute electric polarization from first-principles. They can also be used to represent the electronic systems at fixed electric field and to determine dielectric properties of insulating materials. Here we develop a Wannier-function-based formalism to perform first-principles calculations at fixed polarization. Such an approach allows to extract the polarization-energy landscape of a crystal and thus supports the theoretical investigation of polar materials. To facilitate the calculations, we implement a quasi-Newton method that simultaneously relaxes the internal coordinates and adjusts the electric field in crystals at fixed polarization. The method is applied to study the ferroelectric behavior of mathrmBaTiO_3\mathrm{BaTiO_3}mathrmBaTiO3 and mathrmPbTiO3\mathrm{PbTiO_3}mathrmPbTiO_3 in tetragonal phases. The physical processes driving the ferroelectricity of both compounds are examined thanks to the localized orbital picture offered by Wannier func...