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Physics 5520 : Solid State Physics II

Schedule: Wednesday, Friday, 3:00 pm – 4:20 pm

Location: JFB 103

Instructor: John Lupton, JFB 307 (Phone: 581-6408)

Teaching Assistant: Kipp van Schooten, South Physics 301 (kippvs@physics.utah.edu)

UPDATED Monday, May 05, 2008. -----------PLEASE BE SURE TO PRESS THE RELOAD BUTTON! -------------

Here is the final exam (thanks, Kipp)

Here are the results and your grades – I’m very impressed!

Thanks for all of your hard work. We covered a lot of material. I really enjoyed doing the course and having everyone participate in all of the activities (and do so well in the final) made all the difference. Feel free to drop by to pick up your exam. Have a good summer!

Course outline

As you (should) know, condensed matter physics (as it should be more appropriately named – the name was introduced in the 70s by Anderson) is the most diverse field of physics, covering everything from mechanics to optics, quantum mechanics to statistical physics to quantum field theory. Condensed matter interfaces with devices and applications on the one side and has most recently come close to merging with biological physics. Every second (or so…) Nobel prize (in physics/ chemistry/ physiology) is awarded to a condensed matter physicist, so if you call yourself a physicist, you should really know as much as possible about condensed matter physics. I expect all of you have taken 5510 somewhere along the line. This course is intended to show how much fun physics can be. We will go over the ground work in as much detail as necessary, focusing on concepts rather than on endless derivations, with the aim of bringing you the ability to appreciate some of the most exciting activities at the forefront of physics. I have not fixed the syllabus up front, but will make what we cover dependent on what your interests are. We will discuss this in the first lecture.

General remarks

My goal is for everybody in class to feel confident to ask a question in a condensed matter colloquium in future. I expect that, depending on your interest and motivation, the course will take up roughly 6 hours/week, 3 hours lecture, 1 hour reading/discussion with the TA, 2 hours homework (in this order!).

We’re pretty flexible in terms of course content. On the one hand I’d like to cover as many different things as possible, on the other hand, of course, it has got to be fun for everyone and I really want to make sure you’ve got the core concepts. I expect to be interrupted if you feel you’ve not understood something. Please do not leave it to the final exam to find out that you’ve not understood what an acoustic phonon is!

I would be surprised if you can do OK in the exams and homeworks if you cannot make it to class, so please let me know if there is any problem with you attending.

Recommended text

Everybody should really have a copy of Kittel to refer to. Ashcroft Mermin is the other standard book, but you do not need to rush out and buy it. Other books I can recommend include:

Klingshirn, Semiconductor optics

Parker, Physics of optoelectronics (a bit on the technical side)

Marder, Condensed matter physics

Chaikin and Lubensky, Principles of condensed matter physics

Atkins, Molecular quantum mechanics

Haken and Wolf, Molecular physics

Schwoerer and Wolf, Organic molecular solids

Rosencher and Vinter, Optoelectronics (this has a really good introductory overview of semiconductor optics)

Tanner, Electrons in solids (a manageable size)

Singh, Electronic and optoelectronic properties of semiconductor structures

You may also want to refer to your favourite modern physics textbook now and again.

Don’t believe everything you read on Wikipedia. However, it’s a very handy resource which I recommend you consult frequently.

You are welcome to come by my office and take a look at the books.

Current reading (April 18th):

We’re finishing off with superconductivity.

Kittel Ch. 12

Problem sheets and handouts

I have two handouts to start with: one on your prior knowledge, the other on your interests.

I will provide handouts of any overhead transparencies I use, as well as of the lecture notes (please bear with me, they’re not quite complete yet).

The problems are designed to get you thinking about the material you’ve heard about in the lectures (and should encourage you to read along/ahead a little, too!). There will be some repetition from 5510 in the homeworks, just to make sure the material has sunk in. I will go over some of the homeworks in class, but it really is up to you to have the TA (or myself) take you through whatever you do not understand. Please make as much use of the TA as possible!

Exams

Solution to midterm (thank you, Kipp…)

Review of midterm results

Topics

You can have some say in which topics we cover.

I intend to begin with a 5510 review, moving on to magnetism, superconductivity, semiconductor band structures, electronic structure theory, tight-binding models for the first half of the course.

Increasingly less preliminary course content and schedule:

Date	Topic	Comment	Suggested reading
1/9	Review of 5510
1/11	Review of 5510
1/16	Introduction to crystal structures	Homework 1 out	Kittel, Chapter 1
1/18	X-ray diffraction		Kittel, Chapter 2
1/23	Phonons: scattering	Homework 2 out	Kittel, Chapter 4
1/25	Phonon scattering		Kittel, Chapter 4
1/30	Phonon polaritons	Homework 3 out	Kittel, Chapter 10
2/1	Polaritons / electrons in solids		Kittel, Chapter 10
2/6	Fermi surface of metals		Kittel, Chapter 6
2/8	Properties of Fermi surface	Homework 4 out	Kittel, Chapter 9
2/13	Discussion class	Decide on essay topics
2/15	Band structure/effective masses/ Fermi surface		Kittel, Chapter 9
2/20	Electronic structure / H2 molecule		Ashcroft, Chapter 17
2/22	Electronic structure / Hartree Fock / SCF		Ashcroft, Chapter 17, and a molecular quantum mechanics book, e.g. Atkins or Haken/Wolf.
2/27	Electronic structure / Hückel	Homework 4 due	Atkins is your best bet
2/29	Photonic crystals /Semiconductors		If you want more indepth info, turn to the Joannopoulos book.
3/5	Heterostructure/Quantum structures	Essay due (new!)	This is based on the book by J. Singh.
3/7	Midterm (50 minutes) ; Optoelectronics		Take a look at the Singh book – come to my office
3/12	Optical properties of semiconductors/quantum heterostructures		Ashcroft, Chapter 28 may also help
3/14	Semiconductors / excitons		Ashcroft, Chapter 30 ; also feel free to take a look at my Schwoerer/Wolf book
3/26	Discuss midterm / excitons	We did do a fair amount last week, while some of you were away – please look at the notes and let me know if you want me to go over something again.
3/28	Excitons/Paramagnetism		Kittel 11
4/2	Paramagnetism	Homework 5 out	Kittel 14
4/4	Adiabatic demagnetization		Kittel 14
4/9	Ferromagnetism / mean field theory / spin waves	Homework 6 out	Kittel 15
4/11	Ferromagnetic domains / exchange interactions		Kittel 15
4/16	Spin resonance / Bloch equations	Homework 7 out	Kittel 16
4/18	Superconductivity		Kittel 12
4/23	Superconductivity		Kittel 12

Important dates

2/13 – let me know your essay topic

3/5, 4 pm – Essay due

3/7, 3.00-3:50 pm – Midterm exam

4/30, 3.30 pm – Final exam (2 hours)

Some (helpful?) links

You may like to try this Hyperphysics website

The MIT open course ware website is pretty good (Fall/Spring).

Information on diamagnetism and levitation (with some fun movies).

Forgotten the periodic table?

Office hours

Monday and Thursday, 2:00 – 4:00 pm, JFB 307. I will usually announce if I have to be out of town and can’t make the office hours – generally, if I am not too busy, you are welcome to come round any time.

TA: Kipp van Schooten (kippvs@physics.utah.edu, office South Physics 301, 3^rd floor), office hours Tuesdays 12:00 – 1:00 pm (in the library), and at your discretion! Please make use of this fantastic resource!

These office hours are only suggestions! Let us know if there are any scheduling conflicts.

Homework

There will be 7 sets of homework, typically consisting of 2-3 problems. There may be the odd extra problem (i.e. extra points) labeled by an asterisk. You will probably find it helpful to chat to the TA now and again. Problems are handed out and to be returned on Wednesdays. If you can’t make it to class, make sure your solutions are in Kipp’s letter box by 4 pm.

Exams

There will be one midterm exam and one final exam. We will decide in class whether you’re allowed to take a piece of paper with you for reference or not.

There will be no resit exams – please make sure you make it to the exams. Let me know of any scheduling conflicts immediately!

Essay

The most important skill you can acquire as a graduate student is the ability to assimilate and disseminate information efficiently. We will miss two weeks of homeworks so that you can prepare a 2-3 (max!, preferably 2) page essay (~1000 words, plus diagrams, equations, whatever) on a solid state physics topic of your choice. Your essay should provide an introduction/background, a bit of a historical perspective, a comment on implications and applications, and must, most importantly, highlight the fundamental physics of whatever you are describing. You should aim at not spending more than six hours on this exercise. You will not get any credit for flashy cartoons/pictures, but for a convincing, compelling and concise written presentation (i.e. don’t beat about the bush). I can give you some examples of the kind of stuff we’re looking for.

Handy resources: Nature, Science, Physics Today, New Scientist (within reason), Scientific American, Physics World, Web of Science (www.isiknowledge.com)

You will also have the opportunity to present your essay in a talk (10 minutes+5 minutes discussion). You will get extra points for this (counting towards an extra 5 % of your grade).

The essay is due on Mar. 5^th.

Please let me know by Feb. 13^th which topic you want to work on (it does not have to be from the list below, but I must approve it). I can point you in the direction of some suitable articles if you come and see me.

Examples of possible topics include:

Giant magnetoresistance, fractional quantum hall effect, microfluidics, surface acoustic waves, solid state laser cooling, graphene, negative refraction, molecular magnetism, photomagnetism, spin hall effect, Brownian ratchets, heat transport in carbon nanotubes, quantum cascade lasers, photorefractive effect, molecular photoswitches, neutron scattering, liquid crystals, thermoelectric effect, molecular selfassembly, Kondo effect, spin glasses, Bose-Einstein condensation of excitons, Mössbauer spectroscopy, quasi crystals, optical lattices in BE condensates – tunable “Hubbard” labs.

Evaluation of the essays

I went through the main points in class. Big “no-no”s include lifting other peoples’ words verbatim, and inappropriate or insufficient referencing. A few ideas for the future:

* Use Word, or at least try out the Tex spell checker – typos are entirely avoidable, but such things may cost you a successful job application one day!

* Read your work out ALOUD to yourself (or someone else). You will immediately spot funny sentences and repetitions. Unless you’re Steinbeck, every sentence has a verb. Make sure you know where your verbs are! Don’t double up words, and make yourself sensitive to bootstrapping arguments (usually a risk in long sentences).

* Avoid using first person singular, unless you’re the Pope or the Queen. Some people and journals react very sensitively to this.

* Make sure you explain figures. At the very least put in a figure caption. Linking the text to the figure by a hand waving “(fig. 1)” may make things easier for you, but it will make it harder for the reader.

* Usually you want something from the reader, i.e. you are not providing something in writing out of pure charity. You cannot make it too comfortable for the reader. The more comfortable you make it, the more likely the reader will take you seriously.

A few of you have very kindly agreed to let me post your essays. If your grade didn’t quite meet your expectation, please do take the time to look through these examples and figure out how you can improve in the future. In fact, I’d strongly recommend everybody takes a look at these 5 examples, as they are quite distinct. I’ll give the password in the lecture (or email me).

I also really recommend you take a quick look at this pamphlet, a brief set of instructions on writing from George Whiteside’s group.

Grading Scheme

midterm (15 %), final (30 %), homeworks (40 %), essay (15 %) + presentation (extra 5 %)

I will also take your participation in class into account, i.e. if you are just at the boundary between grades, active participation may help to push you up!

The (very) preliminary grading scheme is A-: 80 %, B-: 60 %, C-: 40 % of available points.

Favourite past user comments

“I think it would really be better to print them (the notes) into your own book and make the students buy the typed up version”

“If the lectures […] (don’t) prepare us for success on the exam, then what are we doing all that work for???”

Academic Integrity

The policy on academic integrity (Student Behavior Code) can be found on the University web site at http://www.admin.utah.edu/ppmanual/8/8-1.html. The student is responsible for reading and understanding this policy. The Student Behavior Code will be strictly followed in this class.

Students with Disabilities

The University of Utah Department of Physics seeks to provide equal access to its programs, services and activities for people with disabilities. If you will need accommodations in this course, reasonable prior notice must be given to the instructor and to the Center for Disability Services, 162 Olpin Union Bldg, 581-5020 (V/TDD) (http://disability.utah.edu/) to make arrangements for accommodations. You are strongly encouraged to come and talk to the instructor about your disability and necessary accommodations within the first two weeks of the semester.

If you have any concerns or whatever DO NOT wait until AFTER the exam to inform us.