First-principles-based calculation of branching ratio for 5d, 4d, and 3dtransition metal systems

Do Hoon Kiem; Jae Hoon Sim; Hongkee Yoon; Myung Joon Han

doi:10.1088/1361-648X/ab786f

First-principles-based calculation of branching ratio for 5d, 4d, and 3dtransition metal systems

Do Hoon Kiem, Jae Hoon Sim, Hongkee Yoon, Myung Joon Han

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

A new first-principles computation scheme to calculate 'branching ratio' has been applied to various 5d, 4d, and 3d transition metal elements and compounds. This recently suggested method is based on a theory which assumes the atomic core hole interacts barely with valence electrons. While it provides an efficient way to calculate the experimentally measurable quantity without generating spectrum itself, its reliability and applicability should be carefully examined especially for the light transition metal systems. Here we select 36 different materials and compare the calculation results with experimental data. It is found that our scheme well describes 5d and 4d transition metal systems whereas, for 3d materials, the difference between the calculation and experiment is quite significant. It is attributed to the neglect of core-valence interaction whose energy scale is comparable with the spin-orbit coupling of core p orbitals.

Original language	English
Article number	245501
Journal	Journal of Physics Condensed Matter
Volume	32
Issue number	24
DOIs	https://doi.org/10.1088/1361-648X/ab786f
State	Published - Jun 3 2020
Externally published	Yes

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title = "First-principles-based calculation of branching ratio for 5d, 4d, and 3dtransition metal systems",

abstract = "A new first-principles computation scheme to calculate 'branching ratio' has been applied to various 5d, 4d, and 3d transition metal elements and compounds. This recently suggested method is based on a theory which assumes the atomic core hole interacts barely with valence electrons. While it provides an efficient way to calculate the experimentally measurable quantity without generating spectrum itself, its reliability and applicability should be carefully examined especially for the light transition metal systems. Here we select 36 different materials and compare the calculation results with experimental data. It is found that our scheme well describes 5d and 4d transition metal systems whereas, for 3d materials, the difference between the calculation and experiment is quite significant. It is attributed to the neglect of core-valence interaction whose energy scale is comparable with the spin-orbit coupling of core p orbitals.",

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AU - Kiem, Do Hoon

AU - Sim, Jae Hoon

AU - Yoon, Hongkee

AU - Han, Myung Joon

PY - 2020/6/3

Y1 - 2020/6/3

N2 - A new first-principles computation scheme to calculate 'branching ratio' has been applied to various 5d, 4d, and 3d transition metal elements and compounds. This recently suggested method is based on a theory which assumes the atomic core hole interacts barely with valence electrons. While it provides an efficient way to calculate the experimentally measurable quantity without generating spectrum itself, its reliability and applicability should be carefully examined especially for the light transition metal systems. Here we select 36 different materials and compare the calculation results with experimental data. It is found that our scheme well describes 5d and 4d transition metal systems whereas, for 3d materials, the difference between the calculation and experiment is quite significant. It is attributed to the neglect of core-valence interaction whose energy scale is comparable with the spin-orbit coupling of core p orbitals.

AB - A new first-principles computation scheme to calculate 'branching ratio' has been applied to various 5d, 4d, and 3d transition metal elements and compounds. This recently suggested method is based on a theory which assumes the atomic core hole interacts barely with valence electrons. While it provides an efficient way to calculate the experimentally measurable quantity without generating spectrum itself, its reliability and applicability should be carefully examined especially for the light transition metal systems. Here we select 36 different materials and compare the calculation results with experimental data. It is found that our scheme well describes 5d and 4d transition metal systems whereas, for 3d materials, the difference between the calculation and experiment is quite significant. It is attributed to the neglect of core-valence interaction whose energy scale is comparable with the spin-orbit coupling of core p orbitals.

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First-principles-based calculation of branching ratio for 5d, 4d, and 3dtransition metal systems

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