PHYS 485 General Information

Physics 485 provides an introduction to quantum physics including suitable for majors in Physics, Electrical Engineering, Materials Science, Chemistry, and related Sciences.

When:

Lectures on Mondays and Wednesdays 2:00 - 3:20 pm.

Midterms: Monday, Oct-14th and Wed, Nov-20th

Final: TBA

Where:

Lectures and exams take place in: 136 Loomis Laboratory of Physics

PHYS 485 Contact Information

Instructor:  Professor Matthias Grosse PerdekampOffice:        469 Loomis LaboratoryPhone:       (217) 333-6544Email:         mgp@illinois.edu Office hours: Tuesday 5:00-6:00pm Grader:      Tsung-Han YehOffice:         Loomis-MRL Interpass 390FPhone:       no office phoneEmail:        tyeh6@illinois.edu Office hours:  Tuesday 4:00-5:00pm

For course related e-mail: if you would like a prompt reply make sure to place “PHYS 485 “ into your subject line

Course web-page:

PHYS 485 Grading Policy

Course grades will be determined by the following percentages:

Problem sets 45%Midterm I 15%Midterm II 15%Final exam 25%

Final grade boundaries will be chosen such that NA++NA+NA- ~ 40% of NAll

and similar for B letter grades .

PHYS 485 Homework

10 problem, one per week. Problem sets will account for 45% of the final grade. Problem sets will be distributed by e-mail Wednesdays by the end of the day and are due one week later, Wednesday in class. Late submission: 485 homework box, 2nd floor.

Late deductions: 20% Wednesday 2.05pm to Thursday 6pm 40% after Thursday 6pm to Friday 6pm 100% after Friday 6pm

Solutions will be posted on the course web-page on Monday morning and homework will be returned during the Monday lectures.

First homework: Wednesday Sep. 4th due Wednesday Sep. 11th. Problem sets aim to enhance your learning of the material. I encourage you toconsult with other students in the class on the problem sets, but remember that you will be on your own in the exams.

TA and lecturer office hours are scheduled Tuesday afternoon.

PHYS 485 Exams

Midterms: There will be two midterm examination, given in class. Each midterm will account for 15% of your final grade.  Midterm I (Monday, October-14, in class)Midterm II (Wednesday, November-20, in class)

Final Exam: There will be a three-hour final exam, which will account for 25% of your final grade.The final exam will cover all course material. All exams are closed book. However, it is permitted to use a one page summary of your own notes during the midterms and three pages for the final. Calculators will be necessary.

About half of the exam problems will be taken from study lists of problems for each exam and the homework.

Textbook:

Quantum Physics of Atoms, Molecules, Solids, Nuclei, and Particles , 2nd Edition,Robert Eisberg and Robert Resnick (1985).

 

Other books you might want to consult:

Quantum Physics, 3rd Edition, Stephen Gasiorowicz (2003).

The Feynman Lectures on Physics, Vol.III, R. Feynman, R. Leighton, M. Sands (1964).

As Reference for selected topics: Quantum Mechanics, C. Choen-Tannoudji, B. Diu, F. Laloe (1992).

Recommended Reading

PHYS 485 Makeup Time & Day

Poll: What is the best time to schedule a Makeup Class if necessary? [I will try to avoid this but it might become necessary ~ 2 times, to acommodate travel to my experiment at BNL]

Tuesday, Thursday, Friday

2-3.20pm 3-4.20pm 4-5.20pm 5-6.20pm 6-7.20pm 7-8.20pm 8-9.20pm

Please raise your hand for times that will not work for you!

Quantum Mechanics

Scope: Quantitative description of phenomena observed in atoms, molecules, nuclei, elementary particles and condensed matter

(in the non-relativistic limit).

The goals of this course are to

(a) review the basic concepts of quantum mechanics (b) study it’s applications for a broad range of different areas: atoms, molecules, condensed matter and nuclei.

In the late 19th and early 20th century physics experiments increasingly gain access to microscopic observables: However, attempts to describe atomic particles as point masses governed by the laws of classical mechanics and field theory (E&M) fail for an increasing set of experimental observations. Examples:

Thermal radiation : “ultraviolet catastrophe” for black body radiators ( Wednesday!)

Atomic spectra : discrete optical emission lines!

Intrinsic orbital angular momentum: spin phenomena, eg. Stern Gerlach experiment can not be explained in the framework of classic physics

Superconductivity : again, no classical explanation

Why Quantum Mechanics ?

A Current Example on How Well Classical Physics Works!

World largest superconducting solenoidupon arrival at Fermi-Lab in July 2013

Classical EM allows perfect description of currents andvoltages in case of an events that leads to the loss ofsuperconductivity in the g-2 magnet:

Fit of classical transformereqns. to highly precise data !

In the late 19th and early 20th century physics experiments increasingly gain access to microscopic observables: However, attempts to describe atomic particles as point masses governed by the laws of classical mechanics and field theory (E&M) fail for an increasing set of experimental observations. Examples:

Thermal radiation : “ultraviolet catastrophe” for black body radiators ( Wednesday!)

Atomic spectra : discrete optical emission lines!

Intrinsic orbital angular momentum: spin phenomena, eg. Stern Gerlach experiment can not be explained in the framework of classic physics

Superconductivity : again, no classical explanation

Why Quantum Mechanics ?

The Stern Gerlach Experiment

. of ondistributi continousa in resulting

directionany in oriented be can oven thein

moments magmentic Ag thephysics classic In

F

is atomssilver theon force The

. spin electron (5s)

outermost theof spin the toalproportion is

atom Ag theof moment magnetic The

z

z

z

B

S

S μ

zz

The Stern Gerlach Experiment

Interesting reading: Physics Today article online

Phys. Today 56(12), 53 (2003); doi: 10.1063/1.1650229View online: http://dx.doi.org/10.1063/1.1650229

Classic Physics vs Quantum Mechanics I

Classical mechanics

Classic Physics vs Quantum Mechanics II

Electrodynamics

Features of classical particles and waves:

deterministic equations well defined quantities measurements can (in principle) be precise and non-invasive

Quantum mechanics

Classic Physics vs Quantum Mechanics III

Classic Physics vs Quantum Mechanics IV

Features of systems governed by quantum physics

wave-particle duality interference uncertainty principle (fundamental limit on measurements) quantization of energy levels (atomic structure) entanglement (Schroedinger’s cat paradox, Einstein, Podolsky Rosen, EPR, paradox) quantum statistics (Pauli exclusion principle, Bose condensation) condensed matter (superconductivity)

Interpretation/philosophical issues

interaction of measurements on system evolution causality, determinism

Historical benchmarks in the development of Quantum Mechanics

Historical benchmarks in the development of Quantum Mechanics