Hyperscript

Advanced Materials B

Part 1: Electronic Materials

© Prof. Dr. Helmut Föll

Matrix of Modules

Hyperscripts of AMAT:
General Information

Index


	This matrix contains all modules (i.e. HTML files) of the Hyperscript. Incomplete modules will be finished and more modules will be added in due time. There are three main levels for organizing the modules:
		Basics Contains some reference information and on occasion longer texts on background knowledge that you should be familiar with.
		Learning (main part) Contains everything that you should know after taking the course.
		Advanced Supplies knowledge beyond the scope of the course that is of some interest. Includes, on occasion, also elaborations about historical, strange or funny stuff relating to topics of the course.
	The main part ("learning") is further subdivided in 4 (vertical) columns and the (horizontal) chapters and sub-chapters which define the matrix. The columns "backbone I" and "backbone II" constitute the hard core of the Hyperscript; the columns "illustrations" and "exercises" intend to help in understanding and to practical applications of what has been learned.
	The cells of the matrix contain all the modules, identified by their filename. The first letter of a filename has a specific meaning not important in this context. The numbers have the following meaning: 1. number = chapter 2. number = subchapter 3. number = running integer

	Color coding of entries
		Blue: Finished to a large degree
		Red: Unfinished to a large degree
		Dark green: Contains JAVA or animation
		Light green: "Multiple Choice" Exercises
		Purple: Required reading Module.
		Pink: Summaries

	Contents	Preface	Books	Running Term
Metafiles

Basics	Backbone I	Backbone II	Illustrations	Exercises	Advanced
1. Introduction
	r1_1_1 General Remarks r1_1_2 How to use the Script r1_1_3 Electronic Mat. and products		i1_1_1 Google and ELMAT p1_1_1 People forget g1_1_2 Illustrating tables g1_1_3 Skeleton foil p1_2_1 Silicone vs. silicon
2. Conductors
2.1 Ohm's Law and Theory of Charge Transport
b2_1_1 Averaging vectors b2_1_3 Function generator	r2_1_1 Ohms Law 1 r2_1_2 Ohms Law 2 r2_1_3 Hall effect r2_1_4 Summary			e2_1_1 Numbers µ s2_1_1 Solution e2_1_1 e2_1_2 Numbers v₀, t, l s2_1_2 Solution e2_1_2 e2_1_3 4 Ghz processor s2_1_3 Solution e2_1_3 c2_1_1 Conductivity 1 c2_1_2 Conductivity 2 c2_1_3 Hall effect

2.2 Materials and Conductivity
	r2_2_1 Metals r2_2_2 Alloys r2_2_3 Non-metals r2_2_4 Summary		t2_2_1 Prop. Metals t2_2_2 Resid. resistance Na g2_2_1 Al on different substr. g2_2_2 r von T	e2_2_1 Quizzes to battery e2_2_2 Resistance solar cell c2_2_1 Metals c2_2_2 Alloys c2_2_3 Non-metals c2_2_4 mc summary	t2_2_1 Requirements ICs t2_2_2 Forgetting r(T) t2_2_3 Li ion battery Stanford Paper Kiel Paper
2.3 General Applications
	r2_3_1 Conductors r2_3_2 Contacts r2_3_3 Resistors and Heating r2_3_4 Summary		t2_3_1 Properties Cu alloys t2_3_2 Ag based contacts t2_3_3 Phase diagram t2_3_4 Conducting polymer t2_3_5 Heating elements t2_3_6 MoSi heater g2_3_1 Max. T heating elem.
2.4 Special Applications
	r2_4_1 Thermionic Emission r2_4_2 Field enhanced/Tunneling r2_4_3 Thermoelectric Effects r2_4_4 Summary			c2_4_1 Electron emission c2_4_3 Thermionic Effects c2_4_4 mc summary	t2_4_1 Tunneling t2_4_2 Thermoelectric effects
2.5 Ionic Conductors
		r2_5_1 General Remarks r2_5_2 Debye Length r2_5_3 Nernsts Law r2_5_4 Summary		e2_5_1 Field Screening s2_5_1 Solution e2_5_1 e2_5_2 Nernst equation s2_5_2 No solution e2_5_2 c2_5_4 Ionic conductors
	2.6 Summary Conductors r2_6_1			c2_6_1 Conductors mc summary
3. Dielectrics
3.1 Definitions and General Relations
b3_1_1 Gauss law	r3_1_1 Basics r3_1_2 Summary			c3_1_1 Dielectrics general
3.2 Polarisation Mechanisms
b3_2_2 Spherical Coordinates	r3_2_1 General remarks r3_2_2 Electronic polarization r3_2_3 Ionic polarization r3_2_4 Orientation polarization r3_2_5 Summary/generalization r3_2_6 Clausius-Mosotti r3_2_7 Summary		i3_2_1 Values for e_r t3_2_1 Mistakes in books	e3_2_1 Max. DK water s3_2_1 Solution 3.2-1 e3_2_2 Interface polarization s3_2_2 Solution 3.2-2 e3_2_3 Electronic polarization s3_2_3 Solution 3.2-3 c3_2_1 Polarization mechanisms c3_2_2 Electronic Polarization c3_2_3 Ionic Polarization c3_2_4 Orientation polarization c3_2_5 Summary/generalization c3_2_7 mc summary	t3_2_1 Paul Langevin
3.3 Frequency Dependence of the Dielectric Constant
b3_3_1 Harmonic oscillator b3_3_2 Fourier transforms b3_3_3 Complex notation	r3_3_1 General remarks r3_3_2 Dipole relaxation r3_3_3 Resonance r3_3_4 Complete e(w) r3_3_5 Summary		t3_3_1 Dielectric function	c3_3_4 Complete e(w)	b3_3_1 Strange words t3_3_2 Beer and Relaxation t3_3_3 Frequency dependence Article Beer decay
3.4 Dynamic Properties
	r3_4_1 Dielectric losses r3_4_2 Summary			c3_4_1 Dielectric losses	t3_4_1 Cooking with microwaves
3.5 Electrical Breakdown and Failure
	r3_5_1 General r3_5_2 Breakdown Mechanisms r3_5_3 Summary			c3_5_1 Dielectric breakdown
3.6 Special Dielectrics
	r3_6_1 Piezo electricity and relations r3_6_2 Ferro electricity r3_6_3 Summary		i3_6_1 Piezoelectric fuel injector	c3_6_1 Piezo and Ferro electricity	t3_6_1 Piezo electricity ferro-electrics t3_6_4 PZT
	3.7 Summary Dielectrics r3_7_1			c3_7_1 Dielectrics mc summary
4. Magnetic Materials
4.1 Definitions and General Relations
b4_1_1 Comparison magn. - electr.	r4_1_1 Basics r4_1_2 Dipole origin r4_1_3 Classification r4_1_4 Summary		i4_1_1 Magnetic moments atoms	c4_1_2 Dipole origin c4_1_3 Classification c4_1_4 mc summary	t4_1_3 Ferromagnetic materials
4.2 Dia- and Paramagnetism
	r4_2_1 Diamagnetism r4_2_2 Paramagnetism r4_2_3 Summary
4.3 Ferromagnetism
	r4_3_1 Mean field theory r4_3_2 Beyond mean field r4_3_3 Magnetic domains r4_3_4 Domain movement r4_3_5 Losses; frequency r4_3_6 Hard/soft magnets r4_3_7 Summary		i4_3_1 Domain structures	e4_3_1 Max. magnetization s4_3_1 No solution 4.3-1 e4_3_2 Magnetic moments Fe, Ni, Co s4_3_2 Solution 4.3-2 c4_3_3 Magnetic domains c4_3_4 Domain movement c4_3_5 Losses and frequency c4_3_7 mc summary	t4_3_2 Giant magnetostriction t4_3_3 Hystereses losses
4.4 Technical Materials and Applications
	r4_4_1 Magnetic materials r4_4_2 Magnetic data storage r4_4_3 Summary			c4_4_1 Applications
	4.5 Summary Magnetic Materials - r4_5_1			c4_5_1 mc Summary
5. Optical Materials and Techniques
5.1 Basic Optics
b5_1_1 Photoelectric effect	r5_1_1 What is light? r5_1_2 Geometric optics r5_1_3 Basic wave optics r5_1_4 Polarization r5_1_5 Summary			e5_1_1 Derive Snellius law s5_1_1 Solution 5.1-1 e5_1_2 photon flux s5_1_2 Solution 5.1-2 e5_1_3 Polarization s5_1_3 Solution 5.1-3 c5_1_1 MC to Basic optics 5.1.1 - 5.1.3 c5_1_4 MC to 5.1.4 c5_1_5 mc Summary	t5_1_1 Newton vs. Huygens t5_1_3 Interference paradox t5_1_4 Details light waves Article Interference paradox
5.2 Optics and Materials
	r5_2_1 Interaction with matter r5_2_2 Feresnel equations r5_2_3 Complex n r5_2_4 Polarizers r5_2_5 Inhomogeneous materials r5_2_6 Generating light r5_2_7 Specialities r5_2_8 Summary		i5_2_1 Complex n Si i5_2_2 Polarizing IR and UV	e5_2_1 Fresnel coefficients s5_2_3 Solution 5.2-1 e5_2_2 Fresnel and LED s5_2_2 Solution 5.2-2 e5_2_3 Attenuation light s5_2_3 Solution 5.2-3 e5_2_4 Brewster Angle s5_2_4 Solution 5.2-4 e5_2_5 Raleigh scattering s5_2_5 Solution 5.2-5 c5_2_1 MC to 5.2.1 c5_2_2 MC to 5.2.2 c5_2_3 MC to 5.2.3	t5_2_3 Lang and Polaroid t5_2_4 Types of Luminescence
5.3 Optical Components
	r5_3_1 Light sources r5_3_2 Processing light r5_3_3 Detecting light r5_3_4 Summary				t5_3_2 History Laser
	5.4 Summary Optics r5_4_1			c5_4_1 mc Summary
Basics	Backbone I	Backbone II	Illustrations	Exercises	Advanced

Module Count (finished modules only)
8	69	9	48	27	34
Grand Total: 195

Hyperscript

Advanced Materials B

Part 1: Electronic Materials

© Prof. Dr. Helmut Föll

Matrix of Modules

Metafiles

1. Introduction

2. Conductors

3. Dielectrics

4. Magnetic Materials

5. Optical Materials and Techniques