SS 2024

Optical properties of solids in external fields I

Click on the following link for an overview of the course content:

https://www.youtube.com/watch?v=S9yM4h9njwE&t=3s 

Vorlesung: Prof. Dr. Heidemarie Schmidt

Übung: M.Sc. Sahitya Varma Vegesna

Semesterzeit:    01.04.2024 - 30.09.2024

Vorlesungszeit:  02.04.2024 - 05.07.2024

1) Hiroyuki Fujiwara, Spectroscopic Ellipsometry: Principles and Applications, Wiley, 2007

https://onlinelibrary.wiley.com/doi/book/10.1002/9780470060193

2) Mark Fox: Optical Properties of Solids, Oxford University Press, 2^nd edition 2010.

https://global.oup.com/academic/product/optical-properties-of-solids-9780199573370?q=Mark%20fox&lang=en&cc=de

3) Sadao Adachi, Properties of Group‐IV, III‐V and II‐VI Semiconductors, John Wiley & Sons, Ltd, 2005 

https://onlinelibrary.wiley.com/doi/book/10.1002/0470090340 

4) Thomas P. Pearsall Quantum photonics Springer

https://www.springer.com/gp/book/9783030473242 

Lectures

PART I  Summer terms:

Introduction

• Classification of optical properties
• Optical coefficients
• The complex refractive index and dielectric constant
• Optical materials
• Characteristic optical properties
• Microscopic models

Electromagnetism in dielectrics

• Electromagnetic fields and Maxwell’s equation
• Electromagnetic waves

Classical propagation

• Propagation of light in dense optical medium
• The dipole oscillator model, Kramers-Kronig relationship
• Dispersion
• Optical anisotropy: birefringence

Quantum theory of radiative absorption and emission

• Einstein coefficient
• Quantum transition rates
• Selection rules

Interband absorption

• Interband transition
• The transition rate for direct absorption
• Band edge absorption in direct gap semiconductors
• Band edge absorption in indirect gap semiconductors
• Interband absorption above the band edge
• Measurement of absorption spectra
• Semiconductor photodetectors

Excitons

• The concept of excitons
• Free excitons
• Free excitons at high densities
• Frenkel excitons

Luminescence

• Light emission in solids
• Interband luminescence
• Photoluminescence

Free electrons

• Plasma reflectivity
• Free carrier conductivity
• Metals
• Doped semiconductors
• Plasmons

Phonons

• Infrared active phonons
• Infrared reflectivity and absorption in polar solids
• Polaritons
• Polarons
• Inelastic light scattering
• Phonon lifetimes

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PART II Winter terms:

Introduction

• Magnetooptical materials
• Electrooptical materials
• Topological materials
• Molecular materials

Band theory

• Metals
• Semiconductors
• Insulators
• Topological insulators
• Molecular materials

Excitons

• Free excitons in external magnetic field
• Free excitons at external electric fields

Luminescence

• Magnetoluminescence
• Electroluminescence

Semiconductor quantum structures

• Quantum confined structures
• Growth and structure of semiconductor quantum wells
• Electronic levels
• Optical absorption and excitons
• The quantum Stark effect
• Optical emission
• Intersubband transitions
• Bloch oscillations
• Growth and structure of semiconductor quantum dots
• Electronic levels

Semiconductor photodetectors

• Photodiodes
• Photoconductive devices
• Photovoltaic devices

Luminescence centers

• Vibronic absorption and emission
• Colour centers
• Paramagnetic impurities in ionic crystals
• Solid state lasers and optical amplifiers
• Phosphors

Optical labels in biotechnology

Nonlinear optics

• The nonlinear susceptibility tensor
• The physical origin of optical nonlinearities
• Second-order nonlinearities
• Third-order nonlinear effects

Single photon detectors and quantum optics

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Exercises

PART I  Summer terms:

The software Complete EASE will be provided for use on a personal computer during the term.

Propagation of light

• Light intensity
• Penetration depth of light
• Definition of optical constants

Dielectrics

• Dielectric polarization
• Dielectric function
• Kramers-Kronig relation

Reflection and transmission of light

• Refraction and Snell’s law
• p- and s-polarized light
• Reflection coefficient, transmission coefficient
• Reflectance and transmittance
• Brewster angle
• Total reflection

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PART II Winter terms:

Optical interference

• Optical interference in thin films
• Optical interference in multilayers

Spectroscopic ellipsometry

• Measured value in ellipsometry (y, D)
• Interpretation of (y, D) with optical constants
• Variation of (y, D) in transparent films
• Variation of (y, D) in absorbing films

Dielectric function models

• Lorentz model
• Sellmeier and Cauchy model
• Tauc-Lorentz model
• Drude model

Effective medium approximation

• Effective medium theories
• Modelling of surface roughness

Literature:

1)     Hiroyuki Fujiwara, Spectroscopic Ellipsometry: Principles and Applications, Wiley, 2007 https://onlinelibrary.wiley.com/doi/book/10.1002/9780470060193

2)     Mark Fox: Optical Properties of Solids, Oxford University Press, 2^nd edition 2010. https://global.oup.com/academic/product/optical-properties-of-solids-9780199573370?q=Mark%20fox&lang=en&cc=de

3)     Sadao Adachi, Properties of Group‐IV, III‐V and II‐VI Semiconductors, John Wiley & Sons, Ltd, 2005 https://onlinelibrary.wiley.com/doi/book/10.1002/0470090340 

4)     Thomas P. Pearsall Quantum photonics Springer https://www.springer.com/gp/book/9783030473242