Effects of the Hubbard U on density functional-based predictions of BiFeO<sub>3</sub>properties

Shenton, J. Kane; Bowler, David R.; Cheah, Wei Li

doi:10.1088/1361-648x/aa8935

Cited by 30 publications

(27 citation statements)

References 65 publications

(108 reference statements)

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“…While standard DFT methods are widely in use for such calculations, experimentally obtained outcomes of BiFeO 3 are more closely comparable to the DFT calculated values when Hubbard U parameter, a measure of effective on-site Coulomb interaction, is chosen carefully. [61][62][63][64][65] Experimentally obtained crystallographic parameters were rened by Rietveld method and their geometry was optimized prior to using them for DFT calculations. PDOS, electronic band structure and optical absorption spectra of both BFO bulk and BFO 160 nanoparticles were obtained via DFT calculations using GGA-PBE functionals.…”

Section: Optical Characterizationmentioning

confidence: 99%

Low temperature synthesis of BiFeO₃nanoparticles with enhanced magnetization and promising photocatalytic performance in dye degradation and hydrogen evolution

2018

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Section: Optical Characterizationmentioning

confidence: 99%

Low temperature synthesis of BiFeO₃nanoparticles with enhanced magnetization and promising photocatalytic performance in dye degradation and hydrogen evolution

2018

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“…All first-principles calculations, including initial structural optimizations of the NEB end-points, were completed with the GGA+U approximation 54,55 to densityfunctional theory which has been used effectively with BiFeO 3 13,56,57 . A U eff = 4 eV value was used to better treat the 3d electrons in Fe which has previously been benchmarked and utilized 13,58,59 . Repeating the calculations after altering the U eff value by 1 eV only changed the magnitude of the net magnetization, and did not alter the direction.…”

Section: B Bifeo3 Calculationsmentioning

confidence: 99%

Discovering minimum energy pathways via distortion symmetry groups

et al. 2018

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Physical systems evolve from one state to another along paths of least energy barrier. Without a priori knowledge of the energy landscape, multidimensional search methods aim to find such minimum energy pathways between the initial and final states of a kinetic process. However in many cases, the user has to repeatedly provide initial guess paths, thus ensuring that the reliability of the final result is heavily user-dependent. Recently, the idea of "distortion symmetry groups" as a complete description of the symmetry of a path has been introduced. Through this, a new framework is enabled that provides a powerful means of classifying the infinite collection of possible pathways into a finite number of symmetry equivalent subsets, and then exploring each of these subsets systematically using rigorous group theoretical methods. The method, which we name the distortion symmetry method (DSM), is shown to lead to the discovery of new, previously hidden pathways for the case studies of bulk ferroelectric switching and domain wall motion in proper and improper ferroelectrics, as well as in multiferroic switching. These provide novel physical insights into the nucleation of switching pathways at experimentally observed domain walls in Ca3Ti2O7, as well as how polarization switching can proceed without reversing magnetization in BiFeO3. Furthermore, we demonstrate how symmetry-breaking from a highly symmetric pathway can be used to probe the non-Ising (Bloch and Néel) polarization components integral to transient states involved in switching in PbTiO3. The distortion symmetry method is applicable to a wide variety of physical phenomena ranging from structural, electronic and magnetic distortions, diffusion, and phase transitions in materials.

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“…However, a number of recent investigations [15,23] have demonstrated that choosing U eff parameter only to match the band gap, may introduce spurious effects for strongly correlated materials. For instance, Shenton et al [15] reported that a U eff value of 5 eV or larger is required to match the experimental band gap of BiFeO 3 . However, the ordering of the Fe d orbitals at the conduction band minimum of BiFeO 3 inverts for U eff > 4 eV.…”

Section: Introductionmentioning

confidence: 99%

First-principles calculation of the electronic and optical properties of Gd2FeCrO6 double perovskite: Effect of Hubbard U parameter

Das

Bhuyan

Basith

2021

Journal of Materials Research and Technology

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We have synthesized Gd2FeCrO6 (GFCO) double perovskite which crystallized in monoclinic structure with P21/n space group. The UV-visible and photoluminescence spectroscopic analyses confirmed its direct band gap semiconducting nature. Here, by employing experimentally obtained structural parameters in first-principles calculation, we have reported the spin-polarized electronic band structure, charge carrier effective masses, density of states, electronic charge density distribution and optical absorption property of this newly synthesized GFCO double perovskite. Moreover, the effects of on-site d-d Coulomb interaction energy (U eff ) on the electronic and optical properties were investigated by applying a range of Hubbard U eff parameter from 0 to 6 eV to the Fe-3d and Cr-3d orbitals within the generalized gradient approximation (GGA) and GGA+U methods. Notably, when we applied U eff in the range of 1 to 5 eV, both the up-spin and down-spin band structures were observed to be direct. The charge carrier effective masses were also found to enhance gradually from U eff = 1 eV to 5 eV, however, these values were anomalous for U eff = 0 and 6 eV. These results suggest that U eff should be limited within the range of 1 to 5 eV to calculate the structural, electronic and optical properties of GFCO double perovskite. Finally we observed that considering U eff = 3 eV, the theoretically calculated optical band gap ∼1.99 eV matched well with the experimentally obtained value ∼2.0 eV. The outcomes of our finding imply that the U eff value of 3 eV most accurately localized the Fe-3d and Cr-3d orbitals of GFCO keeping the effect of self-interaction error from the other orbitals almost negligible. Therefore, we may recommend U eff = 3 eV for first-principles calculation of the electronic and optical properties of GFCO double perovskite that might have potential in photocatalytic and related solar energy applications.

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Effects of the Hubbard U on density functional-based predictions of BiFeO₃properties

Cited by 30 publications

References 65 publications

Low temperature synthesis of BiFeO₃nanoparticles with enhanced magnetization and promising photocatalytic performance in dye degradation and hydrogen evolution

Low temperature synthesis of BiFeO₃nanoparticles with enhanced magnetization and promising photocatalytic performance in dye degradation and hydrogen evolution

Discovering minimum energy pathways via distortion symmetry groups

First-principles calculation of the electronic and optical properties of Gd2FeCrO6 double perovskite: Effect of Hubbard U parameter

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Effects of the Hubbard U on density functional-based predictions of BiFeO3properties

Cited by 30 publications

References 65 publications

Low temperature synthesis of BiFeO3nanoparticles with enhanced magnetization and promising photocatalytic performance in dye degradation and hydrogen evolution

Low temperature synthesis of BiFeO3nanoparticles with enhanced magnetization and promising photocatalytic performance in dye degradation and hydrogen evolution

Discovering minimum energy pathways via distortion symmetry groups

First-principles calculation of the electronic and optical properties of Gd2FeCrO6 double perovskite: Effect of Hubbard U parameter

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Effects of the Hubbard U on density functional-based predictions of BiFeO₃properties

Low temperature synthesis of BiFeO₃nanoparticles with enhanced magnetization and promising photocatalytic performance in dye degradation and hydrogen evolution

Low temperature synthesis of BiFeO₃nanoparticles with enhanced magnetization and promising photocatalytic performance in dye degradation and hydrogen evolution