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Transcript
KING FAHD UNIVERSITY OF PETROLEUM AND MINERALS DEPARTMENT OF PHYSICS Physics 212 Modern Physics - Spring Session 2012 - 2013 (Term 122) Course Schedule and Grading Policy Instructor Office Telephone E-mail Web page : : : : : Office Hours : Lectures : Laboratory : Dr. Abdelkrim Mekki 6/219 (03) 860 4292 [email protected] http://faculty.kfupm.edu.sa/phys/akmekki UTR 10:00 AM - 11:50 AM or by appointment UTR 09:00 AM – 09:50 AM T 02:10 PM – 4:50 PM Room 6/219 Room 6/163 Room 6/239 Course Description: An introductory course in Modern Physics. Topics covered include: Special Theory of Relativity; the Nuclear Atom; Electromagnetic Radiation; Bohr Theory of the atom; the Wave Nature of Matter; Quantum Mechanics in One and Three Dimensions; Atomic X-ray Spectra; Statistical Physics, selected topics in Atomic, Solid State, and Nuclear Physics. Pre-requisites: PHYS 102 General Physics II MATH 102 Calculus II Textbook : "Modern Physics", by R. A. Serway, C. J. Moses and C. A. Moyer, 3nd Ed., Saunders College Publishing (2005). References : 1) A. Baiser, Concepts of Modern Physics , McGraw-Hill, NY (1981), call #: QC 173.B413 2) R. T. Weinder and R. L. Sells, Elementary Modern Phyics, 2nd Ed., Allyn and Bacon Inc., Boston (1980), call #: QC 23.W4 3) S. Thornton and A. Rex, Modern Physics for Scientists and Engineers, 4th Edition, Brooks/Cole (2013) Goals : To introduce the students to the basic concepts of the major theories of the 20th century, namely the special theory of relativity, quantum and statistical mechanics and to discuss some selected topics in atomic, solid state, and nuclear physics. Grading Policy : The course grade will be evaluated as follows: Quizzes Homework Laboratory Presentation Exam 1 Exam 2 Final exam Total %age 10% 10% 10% 10% 15% 15% 30% 100% Laboratory work The lab work score will be based on the lab reports. Lab sessions will start on the second week of classes. Exams Schedule All exams will be of problem solving type. The exams are scheduled as follows: Exam 1 Exam 2 Final Exam Sunday 09 March 2014 Sunday 20 April 2014 Tuesday 20 May 2014 (Chapters 1-4) (Chapters 5-8) (Comprehensive) Policy on make-up exams If you miss a major exam, you should come and see me with your official excuse within three days after the exam. Personal excuses are not allowed. If you miss the exam without a valid excuse, you get a ZERO score for that exam. Attendance: Attendance will be enforced and evaluated according to current university regulations. A DN grade will be given to any student exceeding 9 absences without official excuses and/or three absences in laboratory experiments. Any student in possession of an excuse for officially authorized absence must present this excuse to me no later than one week following his resumption of class attendance. Web page The course web page will provide key information during the semester. It will give the homework assignment, their due date and solution. The exams, homework, and lab grades will be published on the web site on regular basis. Any scheduling information that will change during the semester or important announcements will be posted on the web site and sent to the student by e-mail through Portal. Students are urged to check their e-mail as often as possible. The applets related to a particular section of the course are imbedded in the lecture schedule. They are very helpful in visualizing some of the important concepts in the course. Summary of the main learning outcomes for students enrolled in the course. At the end of this course the student should be able to: 1. Have an ample knowledge about special relativity. 2. Know about the quantum nature of atoms. 3. Solve problems related to quantum mechanics in one, two, and three dimensions. 4. Discuss the quantum theory of the hydrogen atom. 5. Know about the wave nature of matter and the principle of duality. 6. Have a strong knowledge about the various discoveries and experiments related to the discovery of the electron, protons and neutrons. 7. To apply his knowledge in the field of atomic physics, solid state physics, and statistical physics. Physics 212 Lecture Schedule - Term 2014-2 Week 1 2 3 4 5 6 Date Topics Chap. Sect. 26 Jan. 2014 Introduction to the subject 28 Overview; The Principle of Relativity 30 Postulates of Special Relativity and Its Consequences Applet 02 Feb. The Lorentz Transformation 04 Relativistic Momentum, Newton Laws and Energy 06 Relativistic Mechanics Wednesday 06 Feb. 2013- Last day for dropping courses without permanent record 09 Electromagnetic Waves and Blackbody radiation Applet1, Applet 11 Planks Law, Rayleigh-Jeans Law, Quantization of light Applet1 , Applet2 13 The Photoelectric Effect Applet --1 1 --1-3 4, 5 1 2 2 6 1, 2 3, 4 3 1, 2 3 3 3, 4 4 16 18 20 The Compton Effect and Particle Wave Complementarity Atoms and Electrons The Rutherford ModelApplet1, Applet2 The Bohr Atom Applet1 , Applet2 3 4 4 5, 6 1, 2 3 23 25 Bohr correspondence principle, Franck-Hertz Experiment Applet De Broglie Waves and Davisson-Germer Experiment Applet1, Applet2 Phase Velocity and Group Velocity of Waves Applet1 The Heisenberg Uncertainty Principle Particle-Wave Duality of the Electron movie The Born Probabilistic Interpretation Applet1 , Applet2 4 5 4, 5 1, 2 5 5 5 6 3 5 6, 7 1 27 02 March. 04 06 Sunday 09 March 2014 – First Major Exam (Chapters 1 – 4) 6:00 – 8:00 PM, Room 6-106 09 11 13 Review The Schrodinger Equation for Particles Applet The Particle in a Box (One dimension) 6 6 2, 3 4 16 18 20 30 01 April 03 06 08 10 The Finite square well The Quantum Oscillator Expectations Values, Operators and Observables The Square Barrier Barrier Penetration and Applications Particle in a Box (Three Dimensions) Central Forces and Angular Momentum Space Quantization, Quantization of angular momentum Hydrogen-like Atoms, Selection Rules 6 6 6 7 7 8 8 8 8 5 6 7, 8 1 2 1 2 3, 4 5 13 Orbital magnetism, Zeeman Effect, Electron Spin 9 15 The Spin-Orbit Interaction 9 17 The Exclusion Principle 9 Sunday 20 April 2014 – Second Major Exam (Chapters 5 – 8) 6:30 – 8:30 PM, Room 106 20 Review 22 Screening Effects 9 24 The Periodic Table 9 X-ray Spectra and Moseley Law 9 27 Statistical Physics, Maxwell-Boltzmann distribution 10 29 Conditions under which Maxwell-Boltzmann statistics are applicable 10 01 May 1, 2 3 4 14 04 06 08 10 10 11 3, 4 5 1 15 11 13 15 11 12 12 2, 3 1 2 7 8 9 10 11 12 13 Quantum Statistics, Applications Applications of Fermi-Dirac Statistics Molecular Structure, Bonding Mechanisms Molecular Spectra The Solid State, Bonding in Solids Classical Free Electron Model of Metals Tuesday 20 May 2014 - FINAL EXAM (COMPREHENSIVE) 7:00-10:00 PM ---5 6 7 1 2
