Campuses:
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| dgs_advice:graduate_classes [2011/03/01 18:05] – [Classes at 5-level] **staging** kapusta | dgs_advice:graduate_classes [2025/03/21 13:25] (current) – [Classes at 8-level] vinals | ||
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| * Phys 4611. **graduate credits given** Introduction to Space Physics. (3 cr. Prereq–2601, | * Phys 4611. **graduate credits given** Introduction to Space Physics. (3 cr. Prereq–2601, | ||
| * Phys 4621. **graduate credits given** Introduction to Plasma Physics. (3 cr. Prereq–4001, | * Phys 4621. **graduate credits given** Introduction to Plasma Physics. (3 cr. Prereq–4001, | ||
| - | * Phys 4711. Introduction to Optics. (3 cr. Prereq–4002)**have not been offered recently** \\ \\ Modern theoretical and experimental optics broadly defined to include, for example, radio astronomy and particle accelerators. Matrix methods in geometrical optics including charged particle optics; optical detectors and noise; phenomena in intense coherent radiation including nonlinear effects.\\ \\ | + | * Phys 4711. Introduction to Optics. (3 cr. Prereq–4002) **has not been offered recently** \\ \\ Modern theoretical and experimental optics broadly defined to include, for example, radio astronomy and particle accelerators. Matrix methods in geometrical optics including charged particle optics; optical detectors and noise; phenomena in intense coherent radiation including nonlinear effects.\\ \\ |
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| * Phys 5022. Relativity, Cosmology, and the Universe. (4 cr. §AST 5022. Prereq–2601 or #)\\ \\ Large-scale structure and history of universe. Introduction to Newtonian and relativistic world models. Physics of early universe. Cosmological tests. Formation of galaxies.\\ \\ | * Phys 5022. Relativity, Cosmology, and the Universe. (4 cr. §AST 5022. Prereq–2601 or #)\\ \\ Large-scale structure and history of universe. Introduction to Newtonian and relativistic world models. Physics of early universe. Cosmological tests. Formation of galaxies.\\ \\ | ||
| * Phys 5041. Analytical and Numerical Methods of Physics I. (4 cr. Prereq–Grad or #)\\ \\ Survey of mathematical techniques, both analytic and numerical, needed for physics. Application to physical problems.\\ \\ | * Phys 5041. Analytical and Numerical Methods of Physics I. (4 cr. Prereq–Grad or #)\\ \\ Survey of mathematical techniques, both analytic and numerical, needed for physics. Application to physical problems.\\ \\ | ||
| - | * Phys 5042. Analytical and Numerical Methods of Physics II. (4 cr. Prereq–5041 or #) - **not offered very often recently**.\\ Survey of mathematical techniques, both analytic and numerical, needed for physics. Application to physical problems.\\ \\ | + | * Phys 5042. Analytical and Numerical Methods of Physics II. (4 cr. Prereq–5041 or #) - **not offered very often**.\\ Survey of mathematical techniques, both analytic and numerical, needed for physics. Application to physical problems.\\ \\ |
| * Phys 5071. Physics for High School Teachers: Experimental Foundations and Historical Perspectives. (3 cr. Prereq–Gen physics, #; no cr for physics grad or grad physics minor) not offered recently.\\ \\ In-depth examination of a conceptual theme in physics, its experimental foundations and historical perspectives. Kinematics and dynamics from Aristotle through Einstein; nature of charge and light; energy and thermodynamics; | * Phys 5071. Physics for High School Teachers: Experimental Foundations and Historical Perspectives. (3 cr. Prereq–Gen physics, #; no cr for physics grad or grad physics minor) not offered recently.\\ \\ In-depth examination of a conceptual theme in physics, its experimental foundations and historical perspectives. Kinematics and dynamics from Aristotle through Einstein; nature of charge and light; energy and thermodynamics; | ||
| - | * PHYS 5072 Best Practices in College Physics Teaching | + | * PHYS 5072 Best Practices in College Physics Teaching |
| * Phys 5081. Introduction to Biopolymer Physics. (3 cr. §PHYS 4911. Prereq–Working knowledge of [thermodynamics, | * Phys 5081. Introduction to Biopolymer Physics. (3 cr. §PHYS 4911. Prereq–Working knowledge of [thermodynamics, | ||
| * Phys 5201. **Core** Thermal and Statistical Physics. (3 cr; A-F only. Prereq–4201 or equivalent)\\ \\ Principles of thermodynamics and statistical mechanics. Selected applications such as kinetic theory, transport theory, and phase transitions.\\ \\ | * Phys 5201. **Core** Thermal and Statistical Physics. (3 cr; A-F only. Prereq–4201 or equivalent)\\ \\ Principles of thermodynamics and statistical mechanics. Selected applications such as kinetic theory, transport theory, and phase transitions.\\ \\ | ||
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| ===== Classes at 8-level ===== | ===== Classes at 8-level ===== | ||
| ** They are typically taken in the 2nd (and 3rd) year**\\ | ** They are typically taken in the 2nd (and 3rd) year**\\ | ||
| - | | + | * Phys 8011. Quantum Field Theory I. (3 cr.)\\ \\ Second quantization of relativistic wave equations: canonical quantization of the free scalar and Dirac fields. Fields in interaction: |
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| * Phys 8012. Quantum Field Theory II. (3 cr. Prereq–8011 or #)\\ \\ Aspects of general theory of quantized fields, including space-time and discrete transformation properties, the CPT theorem, and the spin-statistics connection. Introduction to functional and path-integral methods. Renormalization group and asymptotic freedom. Semi-classical methods and instantons in gauge theories.\\ \\ | * Phys 8012. Quantum Field Theory II. (3 cr. Prereq–8011 or #)\\ \\ Aspects of general theory of quantized fields, including space-time and discrete transformation properties, the CPT theorem, and the spin-statistics connection. Introduction to functional and path-integral methods. Renormalization group and asymptotic freedom. Semi-classical methods and instantons in gauge theories.\\ \\ | ||
| * Phys 8013. Special Topics in Quantum Field Theory. (3.0 cr. Prereq-8012 or #)\\ \\ Includes non-perturbative methods in quantum field theory, supersymmetry, | * Phys 8013. Special Topics in Quantum Field Theory. (3.0 cr. Prereq-8012 or #)\\ \\ Includes non-perturbative methods in quantum field theory, supersymmetry, | ||
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| * Phys 8601. Plasma Physics I. (3 cr. Prereq–4621, | * Phys 8601. Plasma Physics I. (3 cr. Prereq–4621, | ||
| * Phys 8602. Plasma Physics II. (3 cr. Prereq–8601 or #)\\ \\ Theory of plasma waves and instabilities, | * Phys 8602. Plasma Physics II. (3 cr. Prereq–8601 or #)\\ \\ Theory of plasma waves and instabilities, | ||
| - | * Phys 8611. Cosmic | + | * Phys 8611. Cosmic |
| * Phys 8650. Advanced Topics in Space and Plasma Physics. (3 cr [max 9 cr]. Prereq–8602 or 8611 or #)\\ \\ Topics in plasma waves and instabilities, | * Phys 8650. Advanced Topics in Space and Plasma Physics. (3 cr [max 9 cr]. Prereq–8602 or 8611 or #)\\ \\ Topics in plasma waves and instabilities, | ||
| * Phys 8666. Doctoral Pre-Thesis Credits. (1-6 cr [max 24 cr]. Prereq–Max 6 cr per semester or summer; doctoral student who is doing PhD research but has not passed prelim oral); \\ You should not have to take this for more than one semester - you should take the oral soon if you are in this situation. | * Phys 8666. Doctoral Pre-Thesis Credits. (1-6 cr [max 24 cr]. Prereq–Max 6 cr per semester or summer; doctoral student who is doing PhD research but has not passed prelim oral); \\ You should not have to take this for more than one semester - you should take the oral soon if you are in this situation. | ||
| * Phys 8700. Seminar: Condensed Matter Physics. (1 cr [max 6 cr]; S-N only. Prereq–# | * Phys 8700. Seminar: Condensed Matter Physics. (1 cr [max 6 cr]; S-N only. Prereq–# | ||
| - | * Phys 8701. **Fall 2007 will be the last semester that this will be offered, and it will be the same as 5201.** Statistical Mechanics and Transport Theory I. (3 cr. Prereq–5002 or #)\\ \\ Equilibrium properties of macroscopic classical and quantum systems. Phase transitions and Renormalization Group. Transport theory. Applications to soft condensed matter systems.\\ \\ | ||
| * Phys 8702. Statistical Mechanics and Transport Theory II. (3 cr. Prereq–8701 or #)\\ \\ Equilibrium properties of macroscopic classical and quantum systems. Phase transitions and Renormalization Group. Transport theory. Applications to soft condensed matter systems.\\ \\ | * Phys 8702. Statistical Mechanics and Transport Theory II. (3 cr. Prereq–8701 or #)\\ \\ Equilibrium properties of macroscopic classical and quantum systems. Phase transitions and Renormalization Group. Transport theory. Applications to soft condensed matter systems.\\ \\ | ||
| * Phys 8711. Solid-State Physics I. (3 cr. Prereq–4211, | * Phys 8711. Solid-State Physics I. (3 cr. Prereq–4211, | ||
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| * Phys 8888. **required for PhD**; Thesis Credit: Doctoral. (1-24 cr. Prereq–Prelim Oral exam; **24 cr required**)\\ \\ These credits need to be taken to show that you did significant research work, give credits to the department for its research advising work, and give graduate school a share of tuition money for your research\\ \\ | * Phys 8888. **required for PhD**; Thesis Credit: Doctoral. (1-24 cr. Prereq–Prelim Oral exam; **24 cr required**)\\ \\ These credits need to be taken to show that you did significant research work, give credits to the department for its research advising work, and give graduate school a share of tuition money for your research\\ \\ | ||
| * Phys 8900. Seminar: Elementary Particle Physics. (1 cr [max 6 cr]; S-N only)\\ \\ Elementary particle physics, high energy physics, particle astrophysics and cosmology.\\ \\ | * Phys 8900. Seminar: Elementary Particle Physics. (1 cr [max 6 cr]; S-N only)\\ \\ Elementary particle physics, high energy physics, particle astrophysics and cosmology.\\ \\ | ||
| - | * Phys 8901. Elementary Particle Physics I. (3 cr. Prereq–8001 or #)\\ \\ Types of fundamental interactions. Exact and approximate symmetries and conservation laws. Gauge quanta: gluons, photons, W and Z bosons, gravitons. Fundamental fermions: leptons and quarks. Isotopic and flavor SU(3) symmetries of strong interaction. Heavy hadrons. Amplitudes and probabilities. Quantum chromodynamics.\\ \\ | + | * Phys 8901. Elementary Particle Physics I. (3 cr.)\\ \\ Types of fundamental interactions. Exact and approximate symmetries and conservation laws. Gauge quanta: gluons, photons, W and Z bosons, gravitons. Fundamental fermions: leptons and quarks. Isotopic and flavor SU(3) symmetries of strong interaction. Heavy hadrons. Amplitudes and probabilities. Quantum chromodynamics.\\ \\ |
| * Phys 8902. Elementary Particle Physics II. (3 cr. Prereq–8901 or #)\\ \\ Deep inelastic scattering. Weak interactions of leptons. Semileptonic and nonleptonic weak processes with hadons. Oscillations of neutral Kaons. Violation of CP symmetry in Kaons. Neutrino masses and oscillations. Standard model of the electroweak interaction. Grand unification. Unitarity of the S matrix. Properties of soft pions.\\ \\ | * Phys 8902. Elementary Particle Physics II. (3 cr. Prereq–8901 or #)\\ \\ Deep inelastic scattering. Weak interactions of leptons. Semileptonic and nonleptonic weak processes with hadons. Oscillations of neutral Kaons. Violation of CP symmetry in Kaons. Neutrino masses and oscillations. Standard model of the electroweak interaction. Grand unification. Unitarity of the S matrix. Properties of soft pions.\\ \\ | ||
| * Phys 8911. Introduction to Supersymmetry. (3 cr. Prereq–8011 or #)\\ \\ Motivation. Coleman-Mandula theorem. Supersymmetric Quantum Mechanics. 4D supersymmetry algebra and representations. Extended supersymmetry. N=1 superspace and superfields. Supersymmetric guage theories. Chiral/ | * Phys 8911. Introduction to Supersymmetry. (3 cr. Prereq–8011 or #)\\ \\ Motivation. Coleman-Mandula theorem. Supersymmetric Quantum Mechanics. 4D supersymmetry algebra and representations. Extended supersymmetry. N=1 superspace and superfields. Supersymmetric guage theories. Chiral/ | ||