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Analytic and machine learning approaches to composite quantum impurities

By:

Rzadkowski, Wojciech

Material type: Text

TextPublication details: Institute of Science and Technology Austria 2022Online resources:

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Contents:

Abstract

Acknowledgments

About the Author

List of Publications

Table of Contents

List of Figures

1 Introduction

2 Methods

3 Variational approach to spinful angulon

4 Neural-network quantum states approach to the polaron Hamiltonian

5 Characterizing phase transitions with convolutional neural networks

6 Conclusions

Bibliography

Summary: In this Thesis, I study composite quantum impurities with variational techniques, both inspired by machine learning as well as fully analytic. I supplement this with exploration of other applications of machine learning, in particular artificial neural networks, in many-body physics. In Chapters 3 and 4, I study quasiparticle systems with variational approach. I derive a Hamiltonian describing the angulon quasiparticle in the presence of a magnetic field. I apply analytic variational treatment to this Hamiltonian. Then, I introduce a variational approach for non-additive systems, based on artificial neural networks. I exemplify this approach on the example of the polaron quasiparticle (Fröhlich Hamiltonian). In Chapter 5, I continue using artificial neural networks, albeit in a different setting. I apply artificial neural networks to detect phases from snapshots of two types physical systems. Namely, I study Monte Carlo snapshots of multilayer classical spin models as well as molecular dynamics maps of colloidal systems. The main type of networks that I use here are convolutional neural networks, known for their applicability to image data.

List(s) this item appears in: ISTA Thesis

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Title notes ( 15 )

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Item type	Current library	Call number	Status	Date due	Barcode	Item holds
Book	Library	Quiet Room (Browse shelf(Opens below))	Available		AT-ISTA#002552

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Thesis

Abstract

Acknowledgments

About the Author

List of Publications

Table of Contents

List of Figures

1 Introduction

2 Methods

3 Variational approach to spinful angulon

4 Neural-network quantum states approach to the polaron Hamiltonian

5 Characterizing phase transitions with convolutional neural networks

6 Conclusions

Bibliography

In this Thesis, I study composite quantum impurities with variational techniques, both inspired by machine learning as well as fully analytic. I supplement this with exploration of other applications of machine learning, in particular artificial neural networks, in many-body physics. In Chapters 3 and 4, I study quasiparticle systems with variational approach. I derive a Hamiltonian describing the angulon quasiparticle in the presence of a magnetic field. I apply analytic variational treatment to this Hamiltonian. Then, I introduce a variational approach for non-additive systems, based on artificial neural networks. I exemplify this approach on the example of the polaron quasiparticle (Fröhlich Hamiltonian). In Chapter 5, I continue using artificial neural networks, albeit in a different setting. I apply artificial neural networks to detect phases from snapshots of two types physical systems. Namely, I study Monte Carlo snapshots of multilayer classical spin models as well as molecular dynamics maps of colloidal systems. The main type of networks that I use here are convolutional neural networks, known for their applicability to image data.