Home > Research > Publications & Outputs > Methods for Determination of III-V Semiconducto...

Research

Associated organisational unit

Electronic data

Text available via DOI:

View graph of relations

Methods for Determination of III-V Semiconductor Refractive Indices from Reflectance Interference Fringes

Research output: ThesisMaster's Thesis

Published

Standard

Methods for Determination of III-V Semiconductor Refractive Indices from Reflectance Interference Fringes. / Davis, Sam.
Lancaster University, 2024. 72 p.

Research output: ThesisMaster's Thesis

Harvard

Davis, S 2024, 'Methods for Determination of III-V Semiconductor Refractive Indices from Reflectance Interference Fringes', Masters by Research, Lancaster University. https://doi.org/10.17635/lancaster/thesis/2541

APA

Davis, S. (2024). Methods for Determination of III-V Semiconductor Refractive Indices from Reflectance Interference Fringes. [Master's Thesis, Lancaster University]. Lancaster University. https://doi.org/10.17635/lancaster/thesis/2541

Vancouver

Davis S. Methods for Determination of III-V Semiconductor Refractive Indices from Reflectance Interference Fringes. Lancaster University, 2024. 72 p. doi: 10.17635/lancaster/thesis/2541

Author

Davis, Sam. / Methods for Determination of III-V Semiconductor Refractive Indices from Reflectance Interference Fringes. Lancaster University, 2024. 72 p.

Bibtex

@mastersthesis{794d2634d0a54faa93dfa3cd9a32c85c,
title = "Methods for Determination of III-V Semiconductor Refractive Indices from Reflectance Interference Fringes",
abstract = "Accurate dispersive refractive indices for GaSb and AlAsSb are highly desirable for the design of GaSb-based resonant cavity devices operating in the 2-8 μm range. This dissertation reports on the development of two novel methods for the application of the well-known Swanepoel method in the case where normal incidence reflectance spectra are unavailable. By utilising linear regression of oblique angle reflectance spectra to determine normal incidence values, the required input data for the standard Swanepoel method can be calculated without direct measurement of normal incidence reflectance. Dispersive refractive indices calculated from this first method are shown to be in good agreement with literature data and are applied to the modelling of a DBR stopband, where they show significant improvement in agreement between modelled and measured reflectance when compared to experimental literature. The second method determines non-dispersive infrared refractive indices by a second-order Taylor expansion of Swanepoel{\textquoteright}s equations and is shown to be capable of predicting a reasonable trend in the refractive index of dilute (InAs0.91Sb0.09)xGaSb1−x alloy with increasing indium content.",
author = "Sam Davis",
year = "2024",
month = oct,
day = "24",
doi = "10.17635/lancaster/thesis/2541",
language = "English",
publisher = "Lancaster University",
school = "Lancaster University",

}

RIS

TY - THES

T1 - Methods for Determination of III-V Semiconductor Refractive Indices from Reflectance Interference Fringes

AU - Davis, Sam

PY - 2024/10/24

Y1 - 2024/10/24

N2 - Accurate dispersive refractive indices for GaSb and AlAsSb are highly desirable for the design of GaSb-based resonant cavity devices operating in the 2-8 μm range. This dissertation reports on the development of two novel methods for the application of the well-known Swanepoel method in the case where normal incidence reflectance spectra are unavailable. By utilising linear regression of oblique angle reflectance spectra to determine normal incidence values, the required input data for the standard Swanepoel method can be calculated without direct measurement of normal incidence reflectance. Dispersive refractive indices calculated from this first method are shown to be in good agreement with literature data and are applied to the modelling of a DBR stopband, where they show significant improvement in agreement between modelled and measured reflectance when compared to experimental literature. The second method determines non-dispersive infrared refractive indices by a second-order Taylor expansion of Swanepoel’s equations and is shown to be capable of predicting a reasonable trend in the refractive index of dilute (InAs0.91Sb0.09)xGaSb1−x alloy with increasing indium content.

AB - Accurate dispersive refractive indices for GaSb and AlAsSb are highly desirable for the design of GaSb-based resonant cavity devices operating in the 2-8 μm range. This dissertation reports on the development of two novel methods for the application of the well-known Swanepoel method in the case where normal incidence reflectance spectra are unavailable. By utilising linear regression of oblique angle reflectance spectra to determine normal incidence values, the required input data for the standard Swanepoel method can be calculated without direct measurement of normal incidence reflectance. Dispersive refractive indices calculated from this first method are shown to be in good agreement with literature data and are applied to the modelling of a DBR stopband, where they show significant improvement in agreement between modelled and measured reflectance when compared to experimental literature. The second method determines non-dispersive infrared refractive indices by a second-order Taylor expansion of Swanepoel’s equations and is shown to be capable of predicting a reasonable trend in the refractive index of dilute (InAs0.91Sb0.09)xGaSb1−x alloy with increasing indium content.

U2 - 10.17635/lancaster/thesis/2541

DO - 10.17635/lancaster/thesis/2541

M3 - Master's Thesis

PB - Lancaster University

ER -