SCOUT tutorial 2

- A -

About

absorption

angle of incidence

	Step 1: Homogeneous silver layers
	Configuration of the PL object

anisotropic layer

anisotropic optical properties

automatic fit

	Step 4: Determination of tilt angles from experiments
	Fitting PL spectra

autoscale

averaging

averaging formulas

- B -

back-scattered radiation

backside

Bergman representation

	The problem
	Step 2: Testing simple effective medium models
	Step 3: The Bergman representation

Bergman representation object

broadening

Bruggeman formula

- C -

Conversion

current transport

- D -

database

decimals

definition points

density gradient

dielectric function

	The problem
	Step 2: Testing simple effective medium models
	Step 1: Optical constants
	Reflectance analysis

dielectric function model

dipole approximation

dipole resonance

drag

- E -

effective dielectric function

effective medium

	The problem
	Step 2: Testing simple effective medium models

Effective Medium Approxiamtion

electric field

electronic transition

	Configuration of the PL object
	Fitting PL spectra

electronic transitions

EMA

embedded particle

Emission

Excitation

- F -

film thickness

fit

fit parameters

	Step 3: Tilt angle as master parameter
	Fitting PL spectra

- G -

geometry

	Step 2: Testing simple effective medium models
	Step 3: The Bergman representation

glass

	The problem
	Step 1: Homogeneous silver layers

- H -

halfspace

Help&Manual

host

hypertext jumps

- I -

infrared

inhomogeneities

inhomogeneous

insulator

interactions

interband transitions

interference

interference effects

interference fringes

internal efficiency

	Introduction
	Configuration of the PL object
	Fitting PL spectra

island films

islands

- K -

Kim oscillator

	Step 1: Optical constants
	Configuration of the PL object
	Fitting PL spectra

- L -

layer stack

	Step 2: Layer stack and spectra
	Configuration of the PL object

layer thickness

light wavelength

list of fit parameters

list of layer stacks

list of spectra

	Step 2: Layer stack and spectra
	Configuration of the PL object
	Fitting PL spectra

list of susceptibilities

list of transitions

Looyenga formula

luminescent layer

- M -

magic angle

master parameter

matrix

matrix material

Maxwell Garnett formula

metal islands

microgeometry

molecular orientation

molecules

multiphase-composite

- N -

network

- O -

observation angle

OJL

optical constants

	Step 1: Optical constants
	Introduction
	Reflectance analysis

optical model

orientation

	Introduction
	Step 3: Tilt angle as master parameter

orientation angles

oscillator

oscillator strength

oscillators

Overview

- P -

parameter variation

Parameters

peak

	Introduction
	Configuration of the PL object
	Fitting PL spectra

Percolation

percolation strength

	Step 2: Testing simple effective medium models
	Step 3: The Bergman representation

photoluminescence

PL

PL active layer

PL interpretation

PL layer

PL model

PL radiation

PL sources

PL spectrum

	Configuration of the PL object
	Fitting PL spectra

PL spectrum object

	Introduction
	Configuration of the PL object

PL spectrum window

polarization

	Step 2: Layer stack and spectra
	Configuration of the PL object

porous silicon

	Introduction
	Reflectance analysis
	Fitting PL spectra

- R -

random

random orientation

Range

	Step 2: Layer stack and spectra
	Configuration of the PL object

re-absorption

real part

Reflectance

	Step 1: Homogeneous silver layers
	Reflectance analysis
	Configuration of the PL object

reflection

resonance

resonance frequency

response

	Introduction
	Step 3: Tilt angle as master parameter

rough

- S -

sample inhomogeneities

silicon

	Step 1: Optical constants
	Introduction

silver

	The problem
	Step 1: Homogeneous silver layers

slave parameter

slider

sliders

spectra list

	Configuration of the PL object
	Fitting PL spectra

spectral density

	The problem
	Step 2: Testing simple effective medium models
	Step 3: The Bergman representation

spectral range

	Step 1: Homogeneous silver layers
	Step 2: Testing simple effective medium models
	Step 2: Layer stack and spectra

spectral unit

spectrum simulation

sputtering

sputtering rate

substrate

superposition

susceptibility list

- T -

technical manual

thickness

	Step 2: Testing simple effective medium models
	Step 4: Determination of tilt angles from experiments
	Reflectance analysis
	Fitting PL spectra

thickness variation

tilt angle

	Introduction
	Step 3: Tilt angle as master parameter

transition

transitions

transmission

Transmittance

	Step 1: Homogeneous silver layers
	Configuration of the PL object

- U -

unit

- V -

vibrational mode

vibrational modes

volume fraction

	The problem
	Step 2: Testing simple effective medium models
	Step 3: The Bergman representation

- W -

wavelength

	The problem
	Configuration of the PL object

- X -

x-y-plane

- Z -

z-direction