Kinetic and Thermodynamic Modeling of Nanowire Growth

Erik Mårtensson

Kinetic and Thermodynamic Modeling of Nanowire Growth

Erik Mårtensson

Research output: Thesis › Doctoral Thesis (compilation)

188 Downloads (Pure)

Abstract

This thesis aims to expand on the fundamental knowledge of crystal growth, selectively focusing on the area of particle-seeded nanowire growth in the III-V materials system. The growth process is complex. It typically occurs via the vapor-liquid-solid method, wherein growth material is supplied in the vapor phase, but the solidification process occurs dynamically, layer by layer, via an intermediary liquid particle. This intermediary phase makes it difficult to assess the correlation between these three phases, and how changes in the vapor phase affect the liquid phase and, in turn, the solidification of the nanowire.

This thesis examines the correlation between the vapor, liquid and solid phases, and how the dynamics of the layer-by-layer growth affects the process. This is done in part by combining experimental nanowire growth using metal-organic vapor phase epitaxy with thermodynamic modeling. The main contributions have been in combining thermodynamics, mass transfer and crystal growth kinetics into kinetic Monte Carlo models, and using these models to gain insights into the growth process.

The findings of this thesis can be used both to further develop future theoretical models, and to aid in the development of experimental growth, by providing fundamental insights of the growth process and the affects of varying the experimentally accessible process parameters.

Original language	English
Qualification	Doctor
Supervisors/Advisors	Dick Thelander, Kimberly, Supervisor Johansson, Jonas, Assistant supervisor Lehmann, Sebastian, Assistant supervisor
Award date	2021 Oct 26
Place of Publication	Lund
Publisher	Department of Physics, Lund University
ISBN (Print)	978-91-8039-008-8
ISBN (electronic)	978-91-8039-009-5
Publication status	Published - 2021

Bibliographical note

Defence details
Date: 2021-10-26
Time: 13:15
Place: Lecture hall Rydbergsalen, Department of Physics, Sölvegatan 14, Faculty of Engineering LTH, Lund University, Lund. Zoom: : https://lu-se.zoom.us/j/67026065957?pwd=YTZ6RGVuaXFtRVFqZ1JydGh6NGI5dz09
Passcode: 416469

External reviewer(s)
Name: Voorhees, Peter W.
Title: Prof.
Affiliation: Northwestern University, USA.
---

Subject classification (UKÄ)

Materials Chemistry
Nano-technology
Other Physics Topics

Free keywords

Nanowire
GaAs
InAs
Monte Carlo
Kinetics
Thermodynamics
III-V
Simulation
Fysicumarkivet A:2021:Mårtensson

Access to Document

Erik Mårtensson - Thesis Kappa WebOther version, 5.13 MB

4 Article

Effect of Radius on Crystal Structure Selection in III-V Nanowire Growth
Mårtensson, E. K., Lehmann, S., Dick, K. A. & Johansson, J., 2020, In: Crystal Growth and Design. 20, 8, p. 5373-5379 7 p.
Research output: Contribution to journal › Article › peer-review

Open Access
Independent Control of Nucleation and Layer Growth in Nanowires
Maliakkal, C. B., Mårtensson, E. K., Tornberg, M. U., Jacobsson, D., Persson, A. R., Johansson, J., Wallenberg, L. R. & Dick, K. A., 2020, In: ACS Nano. 14, 4, p. 3868-3875 8 p.
Research output: Contribution to journal › Article › peer-review

Open Access
Simulation of GaAs Nanowire Growth and Crystal Structure
Martensson, E. K., Lehmann, S., Dick, K. A. & Johansson, J., 2019, In: Nano Letters. 19, 2, p. 1197-1203
Research output: Contribution to journal › Article › peer-review

Cite this

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title = "Kinetic and Thermodynamic Modeling of Nanowire Growth",

abstract = "This thesis aims to expand on the fundamental knowledge of crystal growth, selectively focusing on the area of particle-seeded nanowire growth in the III-V materials system. The growth process is complex. It typically occurs via the vapor-liquid-solid method, wherein growth material is supplied in the vapor phase, but the solidification process occurs dynamically, layer by layer, via an intermediary liquid particle. This intermediary phase makes it difficult to assess the correlation between these three phases, and how changes in the vapor phase affect the liquid phase and, in turn, the solidification of the nanowire. This thesis examines the correlation between the vapor, liquid and solid phases, and how the dynamics of the layer-by-layer growth affects the process. This is done in part by combining experimental nanowire growth using metal-organic vapor phase epitaxy with thermodynamic modeling. The main contributions have been in combining thermodynamics, mass transfer and crystal growth kinetics into kinetic Monte Carlo models, and using these models to gain insights into the growth process. The findings of this thesis can be used both to further develop future theoretical models, and to aid in the development of experimental growth, by providing fundamental insights of the growth process and the affects of varying the experimentally accessible process parameters.",

keywords = "Nanowire, GaAs, InAs, Monte Carlo, Kinetics, Thermodynamics, III-V, Simulation, Fysicumarkivet A:2021:M{\aa}rtensson",

author = "Erik M{\aa}rtensson",

note = "Defence details Date: 2021-10-26 Time: 13:15 Place: Lecture hall Rydbergsalen, Department of Physics, S{\"o}lvegatan 14, Faculty of Engineering LTH, Lund University, Lund. Zoom: : https://lu-se.zoom.us/j/67026065957?pwd=YTZ6RGVuaXFtRVFqZ1JydGh6NGI5dz09 Passcode: 416469 External reviewer(s) Name: Voorhees, Peter W. Title: Prof. Affiliation: Northwestern University, USA. --- ",

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publisher = "Department of Physics, Lund University",

type = "Doctoral Thesis (compilation)",

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TY - THES

T1 - Kinetic and Thermodynamic Modeling of Nanowire Growth

AU - Mårtensson, Erik

N1 - Defence details Date: 2021-10-26 Time: 13:15 Place: Lecture hall Rydbergsalen, Department of Physics, Sölvegatan 14, Faculty of Engineering LTH, Lund University, Lund. Zoom: : https://lu-se.zoom.us/j/67026065957?pwd=YTZ6RGVuaXFtRVFqZ1JydGh6NGI5dz09 Passcode: 416469 External reviewer(s) Name: Voorhees, Peter W. Title: Prof. Affiliation: Northwestern University, USA. ---

PY - 2021

Y1 - 2021

N2 - This thesis aims to expand on the fundamental knowledge of crystal growth, selectively focusing on the area of particle-seeded nanowire growth in the III-V materials system. The growth process is complex. It typically occurs via the vapor-liquid-solid method, wherein growth material is supplied in the vapor phase, but the solidification process occurs dynamically, layer by layer, via an intermediary liquid particle. This intermediary phase makes it difficult to assess the correlation between these three phases, and how changes in the vapor phase affect the liquid phase and, in turn, the solidification of the nanowire. This thesis examines the correlation between the vapor, liquid and solid phases, and how the dynamics of the layer-by-layer growth affects the process. This is done in part by combining experimental nanowire growth using metal-organic vapor phase epitaxy with thermodynamic modeling. The main contributions have been in combining thermodynamics, mass transfer and crystal growth kinetics into kinetic Monte Carlo models, and using these models to gain insights into the growth process. The findings of this thesis can be used both to further develop future theoretical models, and to aid in the development of experimental growth, by providing fundamental insights of the growth process and the affects of varying the experimentally accessible process parameters.

AB - This thesis aims to expand on the fundamental knowledge of crystal growth, selectively focusing on the area of particle-seeded nanowire growth in the III-V materials system. The growth process is complex. It typically occurs via the vapor-liquid-solid method, wherein growth material is supplied in the vapor phase, but the solidification process occurs dynamically, layer by layer, via an intermediary liquid particle. This intermediary phase makes it difficult to assess the correlation between these three phases, and how changes in the vapor phase affect the liquid phase and, in turn, the solidification of the nanowire. This thesis examines the correlation between the vapor, liquid and solid phases, and how the dynamics of the layer-by-layer growth affects the process. This is done in part by combining experimental nanowire growth using metal-organic vapor phase epitaxy with thermodynamic modeling. The main contributions have been in combining thermodynamics, mass transfer and crystal growth kinetics into kinetic Monte Carlo models, and using these models to gain insights into the growth process. The findings of this thesis can be used both to further develop future theoretical models, and to aid in the development of experimental growth, by providing fundamental insights of the growth process and the affects of varying the experimentally accessible process parameters.

KW - Nanowire

KW - GaAs

KW - InAs

KW - Monte Carlo

KW - Kinetics

KW - Thermodynamics

KW - III-V

KW - Simulation

KW - Fysicumarkivet A:2021:Mårtensson

M3 - Doctoral Thesis (compilation)

SN - 978-91-8039-008-8

PB - Department of Physics, Lund University

CY - Lund

ER -

Kinetic and Thermodynamic Modeling of Nanowire Growth

Abstract

Bibliographical note

Subject classification (UKÄ)

Free keywords

Access to Document

Fingerprint

Research output

Effect of Radius on Crystal Structure Selection in III-V Nanowire Growth

Independent Control of Nucleation and Layer Growth in Nanowires

Simulation of GaAs Nanowire Growth and Crystal Structure

Cite this