Theoretical developments in low-dimensional magnetic systems

Zhen Zhao

Theoretical developments in low-dimensional magnetic systems

Zhen Zhao

Mathematical Physics

Research output: Thesis › Doctoral Thesis (compilation)

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Abstract

In this thesis, we investigate low-dimensional magnetic systems from the theoretical points of view. To address situations with several and distinct magnetic interactions, we develop different frameworks, including a magnon self-energy approach, a spin dynamical exchange-correlation (xc) field formalism and a scheme combining Matrix Product States method and exact diagonalization/nonequilibrium Green's function methods (MPS + ED/NEGF). By means of effective models, we study topics including magnetic frustration, homogeneous spin chain, magnetic skyrmions, and magnetic impurities.

The thesis is based on four papers: In Paper I, we apply the magnon self-energy approach to study the ground-state properties of two-dimensional Heisenberg models with competing exchange couplings. In Papers II and IV, the dynamical xc field formalism is used to calculate the Green's function. In Paper II, we propose a spin xc field formalism to calculate dynamical spin structure factor of the one-dimensional antiferromagnetic Heisenberg model at zero-temperature. In Paper IV, we investigate the Kondo spectral function by extending the xc field formalism to finite temperatures, and apply the formalism to the single-impurity Anderson model. In Paper III, we propose a MPS + ED/NEGF scheme to calculate the ground-state and dynamical properties of quantum magnetic skyrmions with itinerant electrons explicitly included.

Original language	English
Qualification	Doctor
Awarding Institution	Department of Physics
Supervisors/Advisors	Verdozzi, Claudio, Supervisor Aryasetiawan, Ferdi, Supervisor Deen, Pascale, Assistant supervisor
Award date	2024 Sept 20
Place of Publication	Lund
Publisher	Department of Physics, Lund University
ISBN (Print)	978-91-8104-139-2
ISBN (electronic)	978-91-8104-140-8
Publication status	Published - 2024

Bibliographical note

Defence details
Date: 2024-09-20
Time: 09:00
Place: Rydberg Lecture Hall, Department of Physics, Lund University
External reviewer(s)
Name: Blügel, Stefan
Title: Professor
Affiliation: Forschungszentrum Jülich (FZJ), Germany Peter Grünberg Institut (PGI) & Institute for Advanced Simulation (IAS) D-52425 Jülich, Germany.
---

Subject classification (UKÄ)

Condensed Matter Physics (including Material Physics, Nano Physics)

Free keywords

magnetism
Heisenberg model
magnetic skyrmion
magnetic impurity
exact diagonalization
dynamical exchange-correlation field
MPS
NEGF
Kondo spectral function
Fysicumarkivet A:2024: Zhao

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2 Article

Dynamical exchange-correlation potential formalism for spin- 12 Heisenberg and Hubbard chains: The antiferromagnetic/half-filled case
Zhao, Z., Verdozzi, C. & Aryasetiawan, F., 2023 Dec, In: Physical Review B. 108, 23, 235132.
Research output: Contribution to journal › Article › peer-review

Open Access
Green's function method for the two-dimensional frustrated spin- 12 Heisenberg magnetic lattice
Zhao, Z., Verdozzi, C. & Aryasetiawan, F., 2022 Nov 1, In: Physical Review B. 106, 18, 184417.
Research output: Contribution to journal › Article › peer-review

Open Access

Cite this

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title = "Theoretical developments in low-dimensional magnetic systems",

abstract = "In this thesis, we investigate low-dimensional magnetic systems from the theoretical points of view. To address situations with several and distinct magnetic interactions, we develop different frameworks, including a magnon self-energy approach, a spin dynamical exchange-correlation (xc) field formalism and a scheme combining Matrix Product States method and exact diagonalization/nonequilibrium Green's function methods (MPS + ED/NEGF). By means of effective models, we study topics including magnetic frustration, homogeneous spin chain, magnetic skyrmions, and magnetic impurities.The thesis is based on four papers: In Paper I, we apply the magnon self-energy approach to study the ground-state properties of two-dimensional Heisenberg models with competing exchange couplings. In Papers II and IV, the dynamical xc field formalism is used to calculate the Green's function. In Paper II, we propose a spin xc field formalism to calculate dynamical spin structure factor of the one-dimensional antiferromagnetic Heisenberg model at zero-temperature. In Paper IV, we investigate the Kondo spectral function by extending the xc field formalism to finite temperatures, and apply the formalism to the single-impurity Anderson model. In Paper III, we propose a MPS + ED/NEGF scheme to calculate the ground-state and dynamical properties of quantum magnetic skyrmions with itinerant electrons explicitly included.",

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N1 - Defence details Date: 2024-09-20 Time: 09:00 Place: Rydberg Lecture Hall, Department of Physics, Lund University External reviewer(s) Name: Blügel, Stefan Title: Professor Affiliation: Forschungszentrum Jülich (FZJ), Germany Peter Grünberg Institut (PGI) & Institute for Advanced Simulation (IAS) D-52425 Jülich, Germany. ---

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N2 - In this thesis, we investigate low-dimensional magnetic systems from the theoretical points of view. To address situations with several and distinct magnetic interactions, we develop different frameworks, including a magnon self-energy approach, a spin dynamical exchange-correlation (xc) field formalism and a scheme combining Matrix Product States method and exact diagonalization/nonequilibrium Green's function methods (MPS + ED/NEGF). By means of effective models, we study topics including magnetic frustration, homogeneous spin chain, magnetic skyrmions, and magnetic impurities.The thesis is based on four papers: In Paper I, we apply the magnon self-energy approach to study the ground-state properties of two-dimensional Heisenberg models with competing exchange couplings. In Papers II and IV, the dynamical xc field formalism is used to calculate the Green's function. In Paper II, we propose a spin xc field formalism to calculate dynamical spin structure factor of the one-dimensional antiferromagnetic Heisenberg model at zero-temperature. In Paper IV, we investigate the Kondo spectral function by extending the xc field formalism to finite temperatures, and apply the formalism to the single-impurity Anderson model. In Paper III, we propose a MPS + ED/NEGF scheme to calculate the ground-state and dynamical properties of quantum magnetic skyrmions with itinerant electrons explicitly included.

AB - In this thesis, we investigate low-dimensional magnetic systems from the theoretical points of view. To address situations with several and distinct magnetic interactions, we develop different frameworks, including a magnon self-energy approach, a spin dynamical exchange-correlation (xc) field formalism and a scheme combining Matrix Product States method and exact diagonalization/nonequilibrium Green's function methods (MPS + ED/NEGF). By means of effective models, we study topics including magnetic frustration, homogeneous spin chain, magnetic skyrmions, and magnetic impurities.The thesis is based on four papers: In Paper I, we apply the magnon self-energy approach to study the ground-state properties of two-dimensional Heisenberg models with competing exchange couplings. In Papers II and IV, the dynamical xc field formalism is used to calculate the Green's function. In Paper II, we propose a spin xc field formalism to calculate dynamical spin structure factor of the one-dimensional antiferromagnetic Heisenberg model at zero-temperature. In Paper IV, we investigate the Kondo spectral function by extending the xc field formalism to finite temperatures, and apply the formalism to the single-impurity Anderson model. In Paper III, we propose a MPS + ED/NEGF scheme to calculate the ground-state and dynamical properties of quantum magnetic skyrmions with itinerant electrons explicitly included.

KW - magnetism

KW - Heisenberg model

KW - magnetic skyrmion

KW - magnetic impurity

KW - exact diagonalization

KW - dynamical exchange-correlation field

KW - MPS

KW - NEGF

KW - Kondo spectral function

KW - Fysicumarkivet A:2024: Zhao

M3 - Doctoral Thesis (compilation)

SN - 978-91-8104-139-2

PB - Department of Physics, Lund University

CY - Lund

ER -

Theoretical developments in low-dimensional magnetic systems

Abstract

Bibliographical note

Subject classification (UKÄ)

Free keywords

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Research output

Dynamical exchange-correlation potential formalism for spin- 12 Heisenberg and Hubbard chains: The antiferromagnetic/half-filled case

Green's function method for the two-dimensional frustrated spin- 12 Heisenberg magnetic lattice

Cite this