PHY 492: Nuclear and Elementary Particle Physics

Scheduled Time & Place: 9:05-10:05 M W F, 1308BPS

Instructor: Pawel Danielewicz
Office: 223 Cyclotron
Phone: 333-6330 (5-9672 x. 330 from campus)
E-mail: danielewicz@nscl.msu.edu
Office Hours: 11:20-12:10 M W (or by appointment)

Textbooks:

Required: W. S. C. Williams, Nuclear and Particle Physics (Oxford University Press)

On reserve in Physics Library:
K. K. Krane, Introductory Nuclear Physics
H. Frauenfelder and E. M. Henley, Subatomic Physics
D. H. Perkins, Introduction to High Energy Physics
R. N. Cahn and G. Goldhaber, The Experimental Foundations of High-Energy Physics
CRC Handbook of Physics and Chemistry

Grading (approximate): Homework - 30%, Recitations - 30%, Term Paper - 40%

Average time spent per week on the course is expected at about 10h:

Class - 3h, Reading - 3h, Homework - 4h.

Lecture-Recitation Plan: Lectures - M W, Recitations - F
Students will be assigned presentations of solutions to homework problems at the recitation sessions. These presentations replace exams and quizzes. The recitation sessions are not optional!

Term Paper:
Physics 492 is supposed to fulfill the Tier II writing requirement for physics majors. Therefore a term paper is assigned. The paper should be 20-30 pages long and include equations and figures. It will be graded on style and grammar as well as content and presentation. The paper should be on a topic from nuclear or particle physics, at the level of a Scientific American article, scientifically literate but not too technical.
The first step is to choose a topic for your paper. The topic should not be too narrow, but not too broad either. E.g. you should not embark on presenting the history of nuclear and/or particle physics. If you already have a topic of interest for you in nuclear or high-energy physics, you may choose it. Otherwise, you should search for a topic that would interest you. The possible sources include: the textbook, the books on reserve, other books and articles that you can find using the library's on-line searches (such as Web of Science and INSPEC, besides the plain Magic), Annual Review of Nuclear and Particle Science. The last days of classes will be devoted to the presentation of the term papers.

Tentative Schedule for Term Paper:

Date Due

Feb. 9, Mon Topic w/brief description of planned content

Mar. 1, Mon Outline, list of research to be done

Mar. 17, Wed Progress report

Apr. 7, Wed First draft

Apr. 23, Fri Final paper

Apr. 23(?)-30 Paper presentation

Planned Topics

Introduction
Nuclear Physics
1. Introduction
  1. Discovery of the Electron
  2. Discovery of the Nucleus
  3. Review of Special Relativity
  4. Radioactive Decay
2. Nuclear Sizes from Electron Scattering
3. Nuclear Mass and Binding Energy
4. Radioactivity
  1. Modes of Decay
  2. Beta Decay
  3. Alpha Decay
5. Nuclear Reactions
  1. Kinematics
  2. Discovery of the Neutron
  3. Fusion. CNO Cycle
6. Shell Model of Nuclear Structure
  1. Magic Numbers
  2. Quantum Numbers of Ground and Excited States
High Energy Physics
1. Introduction
  1. Feynman Diagrams
  2. The Yukawa Theory
  3. Kinematics of High-Energy Reactions
2. Hadrons in the Quark Model
  1. Quark Model
  2. Experimental Evidence for Quarks
  3. Confinement
3. Weak Interactions
  1. The Fermi Theory of Beta Decay
  2. Neutrino
  3. W and Z Gauge Bosons
  4. Parity Violation
Nuclear and Particle Astrophysics

Please note:
During the exam week, we meet on Thursday, May 6, 7:45-9:45am, in our regular classroom.

Homework: 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13

Suppl. Reading: Prehistory of Nuclear Physics

Date	Due
Feb. 9, Mon	Topic w/brief description of planned content
Mar. 1, Mon	Outline, list of research to be done
Mar. 17, Wed	Progress report
Apr. 7, Wed	First draft
Apr. 23, Fri	Final paper
Apr. 23(?)-30	Paper presentation