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ISSA  >>  Physics  >>  Graduate Courses
Graduate Courses

All Graduate courses are 3 credits except where noted. See the registrar's web site for the current course offerings. Select "Course Schedules" from the menu.

600-999

500-Level Courses

PEP 500 Physics Review*
A review course in the fundamentals of physics, especially in mechanics and electromagnetism; dynamics of a particle; systems of particles and their conservation laws; motion of a rigid body; electrostatics, magnetic fields and currents; electromagnetic induction.
Prerequisites:  introductory mechanics and electromagnetism courses which employ calculus and vector analysis. Typical text: Halliday, Resnick and Walker, Fundamentals of Physics. No credit for Physics or Engineering Physics majors.

PEP 501 Fundamentals of Atomic Physics*
Electrolysis, Brownian motion; charge and mass of electrons and ions; Zeeman effect; photoelectric effect; reflection, refraction, diffraction, absorption and scattering of X-rays; Compton effect; diffraction of electrons; uncertainty principle; electron optics; Bohr theory of atom; atomic spectra and electron distribution; radioactivity; disintegration of nuclei; nuclear processes; nuclear energy and fission. No credit for Physics majors. Typical text: Weidner and lls, Elementary Modern Physics.

PEP 503 Introduction to Solid State Physics
Description of simple physical models which account for electrical conductivity and thermal properties of solids. Basic crystal lattice structures, X-ray diffraction and dispersion curves for phonons and electrons in reciprocal space. Energy bands, Fermi surfaces, metals, insulators, semiconductors, superconductivity and ferromagnetism. Fall semester. Typical text: Kittel, Introduction to Solid State Physics.
Prerequisites:  PEP 242, PEP 542 or equivalent. Cross-listed with EE 503 and MT 503.

PEP 506 Introduction to Astronomy and Cosmology
Theories of the universe, general relativity, Big Bang cosmology and the inflationary universe; elementary particle theory and nucleosynthesis in the early universe. Observational cosmology; galaxy formation and galactic structure; stellar evolution and formation of the elements. White dwarfs, neutron stars and black holes, planetary systems and the existence of life in the universe.

PEP 507 Introduction to Microelectronics and Photonics
An overview of microelectronics and photonics science and Technology. It provides the student who wishes to specialize in their application, physics or fabrication with the necessary knowledge of how the different aspects are interrelated. It is taught in three modules: design and applications, taught by EE faculty; operation of electronic and photonic devices, taught by Physics faculty; fabrication and reliability, taught by the materials faculty. Cross-listed with EE 507 and MT 507.

PEP 509 Intermediate Waves and Optics
The general study of field phenomena; scalar and vector fields and waves; dispersion phase and group velocity; interference, diffraction and polarization; coherence and correlation; geometric and physical optics. Typical text: Hecht and Zajac, Optics. Spring semester.
Prerequisites:  PEP 209, PEP 542 or equivalent. Cross-listed with EE 509.

PEP 510 Modern Optics Lab
The course is designed to familiarize students with a range of optical instruments and their applications. Included will be measurement of aberrations in optical systems, thin-film properties, Fourier transform imaging systems, nonlinear optics and laser beam dynamics. Fall semester.
Prerequisites:  PEP 509 or consent of the instructor. This course may sometimes be offered in the spring term if space is available.

PEP 512 Introduction to Nuclear Physics and Nuclear Reactors
Historical introduction; radioactivity; laws of statistics of radioactive decay; alpha decay; square well model; gamma decay; beta decay; beta energy spectrum; neutrinos; nuclear reactions; relativistic treatment; semiempirical mass formula; nuclear models; uranium and the transuranic elements; fission; nuclear reactors.

PEP 515-516 Photonics I, II
This course will cover topics encompassing the fundamental subject matter for the design of optical systems. Topics will include optical system analysis, optical instrument analysis, applications of thin-film coatings and opto-mechanical system design in the first term. The second term will cover the subjects of photometry and radiometry, spectrographic and spectrophotometric systems, infrared radiation measurement and instrumentation, lasers in optical systems and photon-electron conversion. Typical texts: Military Handbook 141 (U.S. Govt. Printing Office); S.P.I.E Reprint Series (Selected Issues); W.J. Smith, Modern Optical Engineering .
Prerequisites for this course are either PEP 209 or PEP 509. Cross-listed with EE 515-516 and MT 515-516.

PEP 520 Computational Physics
Both numerical techniques and the elements of continuum mechanics are covered. Numerical methods for integrating Newton’s laws, the heat equation, Poisson’s equation and the fluid flow are discussed. Topics also covered: discrete Fourier transform technique, stability theory and the diagonalization of matrices, and Monte Carlo methods. Course project offers students the opportunity to learn specialized techniques in areas of interest. Spring semester. Typical text: Potter, Computational Physics.

PEP 524 Introduction to Surface Science
A phenomenological and theoretical introduction to the field of surface science including experimental techniques and engineering applications. Topics will include: thermodynamics and structure of surfaces, surface diffusion, electronic properties and space-charge effects, physisorption and chemisorption. Spring semester. Alternate years.

PEP 525 Techniques of Surface Analysis
Lectures, demonstrations and laboratory experiments, selected from among the following topics, depending on student interest: vacuum technology; thin-film preparation; scanning electron microscopy; infrared spectroscopy, ellipsometry; electron spectroscopy; Auger, photoelectron, LEED; ion spectroscopies; SIMS, IBS, field emission; surface properties-area, roughness and surface tension. Alternate years. (See MT 525.)

PEP 527 Mathematical Methods for Physics and Engineering I
Vector and tensor fields and transformation properties under rotation of axes, vector identities, gradient, divergence, curl, tensor contraction, geometric interpretation of symmetric and antisymmetric tensors, divergence-Gauss' theorem for tensor fields and Stokes' theorem, Helmholtz' theorem and scalar and vector potentials. Applications to inertia tensor, particle mechanics, transport, electromagnetism (Maxwell's equations), viscous fluid dynamics (the Navier-Stokes equation, Euler equation, the Bernoulli equation). Introduction to the Dirac delta-function and Green’s function technique for solving linear inhomogeneous equations. Orthogonal curvilinear coordinates (general, also spherical, cylindrical). N-dimensional complex space and unitarity, matrix notation, inverse of matrix, Pauli spin matrices, relativity, Lorentz transformation. Tensors and pseudotensors in n-dimensions. Similarity transformations and diagonalization of Hermitian and unitary matrices, eigenvectors and eigenvalues of Hermitian and unitary matrices, Schmidt orthogonalization. Applications to coupled oscillators, rigid body dynamics, etc. Linear independence and completeness. Functions of a complex variable, analyticity, Cauchy’s theorem, Residue theorem, Taylor and Laurent expansions, classification of singularities, analytic continuation, Liouville’s theorem, multiple-valued functions, contour integration, Jordan’s lemma, applications, asymptotics. Fall Semester.
Prerequisites:  4 semesters undergraduate math courses.

PEP 528 Mathematical Methods for Physics and Engineering II
Introduction to Hilbert space, function vectors, completeness in the strong and weak senses, expansion in complete orthonormal sets of functions, Schmidt orthgonalization. The Weierstrass theorem and completeness of eigenfunctions of a Hermitian operator. Dirac/dyadic notation. Legendre polynomials, spherical harmonics, Fourier series and integral, Laplace transform, multipole expansion. Ordinary differential equations, ordinary point and iteration series solution and power series method, Hermite equation, Schrödinger equation for harmonic oscillator. Regular singular point and the method of Frobenius, including the second solution, Bessel equation. Sturm-Liouville systems and weighted complete orthonormal sets of eigenfunctions, Green’s function determination and solution of the inhomogeneous problem. Partial differential equations, heat equation, wave equation, Poisson equation, solution by transform techniques and Green’s function solution of inhomogeneous initial value and boundary value problems. Linear integral equations, iteration series solution, convergence, Kernels separable in several parts, Hilbert-Schmidt theory, Fredholm theory, Volterra equation. Spring semester.
Prerequisites:  PEP 527.

PEP 538 Introduction to Mechanics
Particle motion in one dimension. Simple harmonic oscillators. Motion in two and three dimensions, kinematics, work and energy, conservative forces, central forces, scattering. Systems of particles, linear and angular momentum theorems, collisions, linear spring systems, normal modes. Lagrange’s equations, applications to simple systems. Introduction to moment of inertia tensor and to Hamilton’s equations.

PEP 540 Physical Electronics
CCharged particle motions in electric and magnetic fields; electron and ion optics; charged particle velocity and mass spectrometry; electron and ion beam confinement; thermionic emission; the Pierce gun; field emission; secondary emission; photoelectric effect; sputtering; surface ionization; volume ionization; Townsend discharge. Typical text: Beck and Ahmed, An Introduction to Physical Electronics.

PEP 541 Physics of Gas Discharges
Charged particle motion in electric and magnetic fields; electron and ion emission; ion-surface interaction; electrical breakdown in gases; dark discharges and DC glow discharges; confined discharge; AC, RF and microwave discharges; arc discharges, sparks and corona discharges; non-thermal gas discharges at atmospheric pressure; discharge and low-temperature plasma generation. Typical texts: J.R. Roth, Industrial Plasma Engineering: Principles, Vol.1 , and Y.P. Raizer, Gas Discharge Physics . Cross-listed with EE 541.

PEP 542 Electromagnetism
Electrostatics; Coulomb-Gauss law; Poisson-Laplace equations; boundary value problems; image techniques;dielectric media; magnetostatics; multipole expansion; electromagnetic energy; electromagnetic induction; Maxwell’s equations; electromagnetic waves, waves in bounded regions, wave equations and retarded solutions; simple dipole antenna radiation theory; transformation law of electromagnetic fields. Spring semester. Typical text: Reitz, Milford and Christy, Foundation of Electromagnetic Theory.

PEP 544 Introduction to Plasma Physics and Controlled Fusion
Plasmas in nature and application of plasma physics; single particle motion; plasma fluid theory; waves in plasmas; diffusion and resistivity; equilibrium and stability; nonlinear effects, thermonuclear reactions; the Lawson condition; magnetic confinement fusion; laser fusion. Fall semester.
Prerequisites:  PEP 542.Typical text: F. Chen, Plasma Physics.

PEP 545 Plasma Processing
Basic plasma physics; some atomic processes; plasma diagnostics. Plasma production; D.C. glow discharges, RF glow discharges; magnetron discharges. Plasma-surface interaction; sputter deposition of thin films; reactive ion etching, ion milling and texturing, electron beam assisted chemical vapor deposition; ion implantation. Sputtering systems; ion sources; electron sources; ion beam handling. Typical texts: Chapman, Glow Discharge Processes ; Brodie, Muray, The Physics of Micro-fabrication . Fall semester.

PEP 550 Fluid Mechanics
Description of principle flow phenomena: pipe and channel flows, laminar flow, transition, turbulence; flow past an object-boundary layer, wake, separation, vortices, drag; convection in horizontal layers-conduction, convection, transition from periodic to chaotic behavior. Equations of motion; dynamical scaling; simple viscous flows; inviscid flow; boundary layers, drag and lift; thermal flows; flow in rotating fluids; hydro-dynamic stability; transitions to turbulence. Typical text: Tritton, Physical Fluid Dynamics.

PEP 551 Advanced Physics Laboratory I
An experimental presentation of the evidence for atomic and nuclear theories; typical experiments are: excitation potentials; electronic charge; specific charge of the electron; the Balmer series; Zeeman splitting; spectroscopic isotope shifts; the photovoltaic effect; the Hall effect; gamma ray spectrometry; beta ray spectrometry; neutron activation of nuclides; statistics of counting processes; optical and X-ray diffraction; the Langmuir probe; nuclear magnetic resonance. Fall semester, repeated second semester. By arrangement. Laboratory fee $5. Typical texts: Young, Statistical Treatment of Experimental Data; Melissinos, Experiments in Modern Physics.
Prerequisites:  PEP 222.

PEP 553 Introduction to Quantum Mechanics
This course is an introduction to Schrödinger wave mechanics for students in physics and engineering with an emphasis on engineering applications. This is a required course for all physics undergraduates as well as students in the Microelectronics and Photonics M.S./M.E. degree program and other professional M.S./M.E. degree programs. Topics discussed include one dimensional infinite and finite quantum wells, barrier penetration and scattering in one dimension, linear harmonic oscillator, Kronig-Penney model, angular momentum, central force problems including the hydrogen atom, and spin. Typical texts: Introductory Quantum Mechanics by R. L. Liboff and Quantum Mechanics Fundamentals and Applications to Technology by J. Singh.
Prerequisites:  Ma 221 and PEP 242 or equivalent.

PEP 554 Quantum Mechanics I
This course is meant as the first in a two-course sequence on non-relativistic quantum mechanics for physics graduate students with an emphasis on applications to atomic, molecular and solid state physics. Undergraduate students may take this course as a Technical Elective. Topics covered include: review of Schrödinger wave mechanics; operator algebra, theory of representation and matrix mechanics; symmetries in quantum mechanics; spin and formal theory of angular momentum including addition of angular momentum; approximation methods for stationary problems including time independent perturbation theory, WKB approximation and variational methods. Typical text: Quantum Mechanics by E. Merzbacher.
Prerequisites:  PEP 553, PEP 538, and PEP 527 or equivalent.

PEP 555 Statistical Physics and Kinetic Theory
Kinetic theory: ideal gases, distribution functions, Maxwell-Boltzmann distribution, Boltzmann equation, H-theorem and entropy, simple transport theory. Thermodynamics: review of first and second laws, thermodynamic potentials, Legendre transformation, phase transitions. Elementary statistical mechanics: introduction to microcanonical, canonical and grand canonical distributions, partition functions, simple applications including ideal Maxwell-Boltzmann, Einstein-Bose and Fermi-Dirac gases, paramagnetic systems, blackbody radiation. Typical text: Reif, Statistical and Thermal Physics.

PEP 561 Solid State Electronics for Engineering I
This course introduces fundamentals of semiconductors and basic building blocks of semiconductor devices that are necessary for understanding semiconductor device operations. It is for first-year graduate students and upper-class undergraduate students in electrical engineering, applied physics, engineering physics, optical engineering and materials engineering, who have no previous exposure to solid state physics and semiconductor devices. Topics covered will include description of crystal structures and bonding; introduction to statistical description of electron gas; free-electron theory of metals; motion of electrons in periodic lattice-energy bands; Fermi levels; semiconductors and insulators; electrons and holes in semiconductors; impurity effects; generation and recombination; mobility and other electrical properties of semiconductors; thermal and optical properties; p-n junctions; metal-semiconductor contacts. Cross-listed with EE 561 and MT 561.

PEP 562 Solid State Electronics for Engineering II
This course introduces operating principles and develops models of modern semiconductor devices that are useful in the analysis and design of integrated circuits. Topics covered include: charge carrier transport in semiconductors; diffusion and drift, injection and lifetime of carriers; p-n junction devices; bipolar junction transistors; metal-oxide-semiconductor field effect transistors; metal-semiconductor field effect transistors and high electron mobility transistors; microwave devices; light emitting diodes, semiconductor lasers and photodetectors; integrated devices. Cross-listed with EE 562 and MT 562.

PEP 570 Guided-Wave Optics
Review of electromagnetic theory; derivation of Fresnels’ equations; guided-wave propagation by metallic and dielectric waveguides including step-index optical fibers, graded-index fibers; optical transmission systems; nonlinear effects in optical fibers, solitons and fiber-optic gyroscope.

PEP 575 Fundamentals of Atmospheric Radiation and Climate
This course treats scattering, absorption and emission of electromagnetic radiation in planetary media. The radiative transfer equation is derived, approximate solutions are found. Important heuristic models (Lorentz atom, two-level atom, vibrating rotator) as well as fundamental concepts are discussed including reflectance, absorptance, emittance, radiative warming/cooling rates, actinic radiation, photolysis and biological dose rates. A unified treatment of radiative transfer within the atmosphere and ocean is provided, and extensive use of two-stream and approximate methods is emphasized. Applications to the climate problem focus on the role of greenhouse gases, aerosols and clouds in explaining the temperature structure of the atmosphere and the equilibrium temperature of the earth. The course is suitable for beginning graduate and upper-level undergraduate students.
Prerequisites:  undergraduate calculus, ordinary differential equations (Ma 221 or equivalent) and basic modern physics (PEP 201 or PEP 242 or equivalent).

PEP 577 Laser Theory and Design
An introductory course to the theory of lasers; treatment of spontaneous and stimulated emission, atomic rate equations, laser oscillation conditions, power output and optimum output coupling; CW and pulsed operation, Q switching, mode selection and frequency stabilization; excitation of lasers, inversion mechanisms and typical efficiencies; detailed examination of principal types of lasers, gaseous, solid state and liquid; chemical lasers, dye lasers, Raman lasers, high power lasers, TEA lasers, gas dynamic lasers. Design considerations for GaAlAs, argon ion, helium neon, carbon dioxide, neodymium YAG and pulsed ruby lasers. Fall semester. Typical text: Yariv, Optical Electronics.

PEP 578 Laser Applications and Advanced Optics
Integrated optics, nonlinear optics, Pockels effect, Kerr effect, harmonic generation, parametric devices, phase conjugate mirrors, phase matching. Coherent and incoherent detection, Fourier optics, image processing and holography and Gaussian optics. Detection of light, signal to noise, PIN and APD diodes, optical communication. Scattering of light, Rayleigh, Mie, Brillouin, Raman and Doppler shift scattering. Spring semester.

PEP 580 Electronic Materials and Devices
Electronic, magnetic, optical and thermal properties of materials, the description of these properties based on solid state physics. Description and principles of operation of devices. Spring semester.

PEP 585 Physical Design of Wireless Systems
Physical design of wireless communication systems, emphasizing present and next generation architectures. Impact of non-linear components on performance; noise sources and effects; interference; optimization of receiver and transmitter architectures; individual components (LNAs, power amplifiers, mixers, filters, VCOs, phase-locked loops, frequency synthesizers, etc.); digital signal processing for adaptable architectures; analog-digital converters; new component technologies (SiGe, MEMS, etc.); specifications of component performance; reconfigurability and the role of digital signal processing in future generation architectures; direct conversion; RF packaging; minimization of power dissipation in receivers. Cross-listed with EE/MT 585.

PEP 595 Reliability and Failure of Solid State Devices
This course deals with the electrical, chemical, environmental and mechanical driving forces that compromise the integrity and lead to the failure of electronic materials and devices. Both chip and packaging level failures will be modeled physically and quantified statistically in terms of standard reliability mathematics. On the packaging level, thermal stresses, solder creep, fatigue and fracture, contact relaxation, corrosion and environmental degradation will be treated.
Prerequisites:  PEP 507. Cross-listed with MT/EE 595.

PEP 596 Microfabrication Techniques
Deals with aspects of the technology of processing procedures involved in the fabrication of microelectronic devices and microelectromechanical systems (MEMS). Students will become familiar with various fabrication techniques used for discrete devices as well as large-scale integrated thin-film circuits. Students will also learn that MEMS are sensors and actuators that are designed using different areas of engineering disciplines and they are constructed using a microlithographically-based manufacturing process in conjunction with both semiconductor and micromachining microfabrication technologies.
Prerequisites:  PEP 507. Cross-listed with MT/EE 596.

Courses Numbered 600 and Above

PEP 601 Fundamentals of Data Transmitting
This course is the first part of the graduate certificate program “Wireless Secure Network Design,” which also includes three other courses: PEP 602, 603 and 604. Program focuses on heterogeneous wireless systems used by first-responders – police, fire fighters, National Guard and other emergency forces – to protect the public during large scale crises, such as natural disasters and acts of terrorism. The program also includes analysis of homeland defense, financial and military operations using secure wireless systems. At the end of the program students will learn how to protect existing wireless systems and how to design highly secure systems for a future use. The course presents a comprehensive analysis of different parts of the electromagnetic spectrum, transmission and modulation technologies, hardware, new artificially engineered materials and MEMS with accent on security and robustness of communications.
Prerequisites:  PEP 507 and PEP 585 or permission of instructor.

PEP 602 Secure and Robust Communications
This course presents an overview of areas of first responders', military activities and use of different heterogeneous wireless systems during large scale crises, such as natural disasters, acts of terrorism and during homeland defense, financial and military operations. The course includes an analysis of different wireless network architectures from a security point of view. The course is the second part of the graduate certificate program “Wireless Secure Network Design” which also includes three other courses: PEP 601, 603 and 604.
Prerequisites:  PEP 601.

PEP 603 Physical and Logical Security
This course presents an overview of different methods of authentication and authorization in secure wireless networks. The course focuses on different methods of physical data and link protection, probability of detection and interception, anti-jam and covert capabilities, active and passive protection methods and equipment. The course is the third part of the graduate certificate program “Wireless Secure Network Design” which also includes three other courses: PEP 601, 602 and 604.
Prerequisites:  PEP 601, PEP 602.

PEP 604 Secure Telecom Wireless System Design
This course presents an overview of different methods used in secure heterogeneous wireless systems design. Large scale infrastructure and ad hoc networks test and simulation are major parts of the course. The course also includes practical exercises and lab experiments. The course is the last part of the graduate certificate “Wireless Secure Network Design” which includes also three other courses: PEP 601, 602 and 603. Students who have successfully finished all four courses will receive a graduate certificate in wireless secure network design.
Prerequisites:  PEP 601, PEP 602, PEP 603.

PEP 607/608 Plasma Physics III*
Motion of charged particles in electromagnetic field; Boltzmann equation for plasma; properties of magnetoplasmas; fundamentals of magnetohydrodynamics. Applications to include: mirror geometry, high frequency confinement, plasma confinement and heating by means of magnetic fields; motion of plasmas along and across magnetic field lines; magnetohydrodynamic stability theory; plasma oscillations, microinstabilities waves in magnetoplasma; dispersion relations; Fokker-Planck equation for plasmas; plasma conductivity; runaway electrons; relaxation times; radiation phenomena in magnetoplasmas; stability theories; finite Larmor radius stabilization; minimum-B stability; universal instabilities. Typical text: Schmidt, Physics of High Temperature Plasmas. Fall and spring semester.
Prerequisites:  PEP 642, PEP 643 and PEP 555.

PEP 610 Advanced Modern Optics Lab*
A continuation of PEP 510 for those students desiring a more thorough knowledge of optical systems. Included would be the use of an OTDR, ellipsometry, vacuum deposition of thin films and other instrumentation. Students are encouraged to pursue their individual interests using the available equipment.
Prerequisites:  PEP 510 or the consent of the instructor.

PEP 619 Solid State Devices
Operating principle, modeling and fabrication of solid state devices for modern optical and electronic system implementation; recent developments in solid state devices and integrated circuits; devices covered include bipolar and MOS diodes and transistors, MESFET, MOSFET transistors, tunnel, IMPATT and BARITT diodes, transferred electron devices, light emitting diodes, semiconductor injection and quantum-well lasers, PIN and avalanche photodetectors.
Prerequisites:  EE 503 or equivalent. Cross-listed with EE 619.

PEP 621 Quantum Chemistry
Theorems and postulates of quantum mechanics; operator relationships; solutions of the Schrödinger equation for model systems; variational and perturbation methods; pure spin states; Hartree-Fock self-consistent field theory; applications to many-electron atoms and molecules.
Prerequisites:  Ch 520 or PEP 554 or equivalent.

PEP 626 Optical Communication Systems
Components for and design of optical communication systems; propagation of optical signals in single mode and multimode optical fibers; optical sources and photodetectors; optical modulators and multiplexers; optical communication systems: coherent modulators, optical fiber amplifiers and repeaters; transcontinental and transoceanic optical telecommunication system design; optical fiber local area networks. Cross-listed with EE 626, MT 626 and NIS 626.

PEP 630 Nonlinear Dynamics
Definition of dynamical systems; phase space, equilibrium states and their classification; nonlinear oscillator without and with dissipation; Van der Pol generator; Poincare map; slow and fast motion; forced nonlinear oscillator: linear and nonlinear resonances; forced generators: synchronization; Poincaré indices and bifurcations; solitons; shock waves; weak turbulence; regular patterns in dissipative media; chaos: fractal dimension, Lyapunov exponents. Typical textbooks: H.D.I. Abarbanel, M.I. Rabinovich and M.M. Sushchik, Introduction to Nonlinear Dynamics for Physicists; R.H. Abraham and C.D. Shaw, Dynamics: The Geometry of Behavior.
Prerequisites:  PEP 528 or permission of the instructor.

PEP 642 Mechanics
Lagrangian and Hamiltonian formulations of mechanics, rigid body motion, elasticity, mechanics of continuous media, small vibration theory, special relativity, canonical transformations, perturbation theory. Typical text: Classical Mechanics.

PEP 643 Electricity and Magnetism I
Electrostatics, boundary value problems, Green’s function techniques, methods of image, inversion and conformal mapping; multipole expansion. Magnetostatics, vector potential. Maxwell’s equations and conservation laws. Electromagnetic wave propagation in media. Crystal optics. Fall semester. Typical texts: Jackson, Classical Electrodynamics; Laundau and Lifshitz, Electrodynamics in Continuous Media.
Prerequisites:  PEP 528 and PEP 542.

PEP 644 Electricity and Magnetism II
Interaction of electromagnetic waves with matter, dispersion, waveguides and resonant cavities, radiating systems, scattering and diffraction, covariant electromagnetic theory, motion of relativistic particles in electromagnetic fields, relativistic radiation theory, radiation damping and self-fields. Spring semester. Typical texts: Jackson, Classical Electrodynamics and Laundau and Lifshitz, The Classical Theory of Fields, Electrodynamics in Continuous Media.
Prerequisites:  PEP 643.

PEP 651 Advanced Physics Laboratory II*
Advanced laboratory work in modern physics arranged to suit your requirement. Fall and spring semesters. Laboratory fee: $5. Typical text: see PEP 551.
Prerequisites:  PEP 551.

PEP 653 Quantum Mechanics II
This course is a continuation of PEP 554. Topics include: principles of quantum dynamics, time dependent perturbation theory, scattering theory, the density matrix, quantization of the electromagnetic field, interaction of photons with atoms and non-relativistic particles, identical particles and second quantization for many-body systems. Typical text: Quantum Mechanics by E. Merzbacher.
Prerequisites:  PEP 554 and PEP 542 or equivalent.

PEP 661/662 Solid State Physics III
Crystal symmetry. Space-group-theory analysis of normal modes of lattice vibration, phonon dispersion relations; Raman and infrared activity. Crystal field splitting of ion energy level and transition selection rules. Bloch theorem and calculation of electronic energy bands through tight binding and pseudopotential methods for metals and semiconductors, Fermi surfaces. Transport theory, electrical conduction, thermal properties, cyclotron resonance, de Haas van Alfen and Hall effects. Dia-, para- and ferro-magnetism, magnon spinwaves. Fall and spring semester. Typical texts: Callaway, Quantum Theory of Solid State; Ashcroft and Mermin, Solid State Physics; Kittel, Quantum Theory of Solids. Recommended: PEP 503 and PEP 553-554.

PEP 667 Statistical Mechanics
Advanced transport theory, classical statistical mechanics, fluctuation theory, quantum statistical mechanics, ideal Bose and Fermi gases, imperfect gases, phase transitions, superfluids, Ising model critical phenomena, renormalization group. Typical text: Huang, Statistical Mechanics.

PEP 678 Physics of Optical Communication Systems
The physics behind modern optical communication systems and high data rate communication systems; information theory and light propagation in optical fiber wave guide channels; semiconductor laser sources and detectors; digital optical communication systems; quantum optical information theory; coherence and quantum correlations; optical solution-based communication; squeezed light and noise limitations; coherent optical communication systems; de-phasing and de-coherence; teleportation, cryptography and fractal optics.
Prerequisites:  PEP 542, PEP 554, and PEP 503.

PEP 679 Fourier Optics
Abbe diffraction theory of image formation, spatial filtering, coherence lengths and areas. Holograms; speckle photography; impulse response function; CTF, OTF and MTF of lens system; coherent and incoherent optical signal processing. Spring semester. Typical text: Goodman, Introduction to Fourier Optics.

PEP 680 Quantum Optics
This course explores the quantum mechanical aspects of the theory of electromagnetic radiation and its interaction with matter. Topics covered include Einstein’s theory of emission and absorption, Planck’s law, quantum theory of light-matter interaction, classical fluctuation theory, quantized radiation field, photon quantum statistics, squeezing, nonlinear interactions. Offered in alternate years. Typical text: Loudon, Quantum Theory of Light.
Prerequisites:  PEP 542 or equivalent, PEP 554 and PEP 509.

PEP 690 Introduction to VLSI Design
This course introduces students to the principles and design techniques of very large scale integrated circuits (VLSI). Topics include: MOs transistor characteristics, DC analysis, resistance, capacitance models, transient analysis, propagation delay, power dissipation, CMOS logic design, transistor sizing, layout methodologies, clocking schemes, case studies. Students will use VLSI CAD tools for layout and simulation. Selected class projects may be sent for fabrication. Cross-listed with CpE 690 and MT 690.

PEP 691 Physics and Applications of Semiconductor Nanostructures
This course is intended to introduce the concept of electronic energy band engineering for device applications. Topics to be covered are electronic energy bands, optical properties, electrical transport properties of multiple quantum wells, superlattices, quantum wires and quantum dots; mesoscopic systems, applications of such structures in various solid state devices, such as high electron mobility, resonant tunneling diodes and other negative differential conductance devices, double-heterojunction injection lasers, superlattice-based infrared detectors, electron-wave devices (wave guides, couplers, switching devices) and other novel concepts and ideas made possible by nano-fabrication technology. Fall semester. Typical text: M. Jaros, Physics and Applications of Semiconductor Microstructures; G. Bastard, Wave Mechanics Applied to Semiconductor Heterostructures.
Prerequisites:  Basic knowledge in quantum mechanics and solid state physics (at the levels of PEP 553, PEP 503).

PEP 700 Quantum Electron Physics and Technology Seminar
This seminar is focused on nanostructure-scale electron systems that are so small that their dynamic and statistical properties can only be properly described by quantum mechanics. This includes many submicron semiconductor devices based on heterostructures, quantum wells, superlattices, etc., and it interfaces solid state physics with surface physics and optics. Outstanding visiting scientists make presentations, as well as some faculty members and doctoral research students discussing their thesis work and related journal articles. Participation in these seminars is regarded as an important part of the research education of a physicist working in condensed matter physics and/or surface physics and optics. One-half credit per semester. PEP 700 and PEP 701 may be taken for up to three credits. Pass/Fail.

PEP 701 Topics in Physics and Engineering Physics*
This seminar is focused on current topics in physics and their applications in various areas. The format of the seminar is similar to PEP 700, but the scope of the seminar covers a broader range of topics including interdisciplinary areas and applications such as low-temperature plasma science and technology, atmospheric and environmental science and technology, and other topics. One-half credit per semester. PEP 700 and PEP 701 may be taken for up to three credits. Pass/Fail.

PEP 704 Group Theory for Physicists in Solid State and Molecular Physics
Group theory for physicists with applications to solid state and molecular physics. Relation between group theory and quantum (or classical) mechanics, between classes and observables, between representations and states. Point groups: full rotation group, crystallographic point groups, spin-associated double groups. Crystal field theory with and without spin; selection rules and character tables, use of product representation. Form of macroscopic crystal tensors molecular vibrational states and spectra. Translational properties of crystals. Energy band structure. Formal classification of space groups with examples. Time reversal and Onsager relations with examples. Lattice vibrations and phonons. Localized valence orbitals in chemistry. Hartree-Fock many-electron wave-functions. Phase transitions. Representative texts: M. Lax Symmetry, Principles in Solid State and Molecular Physics; Heine Group, Theory in Quantum Mechanics.
Prerequisites:  Course equivalent to PEP 554 in quantum mechanics and associated mathematics of operators and Hilbert spaces.

PEP 722 Molecular Spectroscopy
Theoretical foundations of spectroscopic methods and their application to the study of atomic and molecular structure and properties; theory of absorption and emission of radiation; line spectra of complex atoms; group theory; rotational, vibrational and electronic spectroscopy of diatomic and polyatomic molecules; infrared, Raman, uv-vis spectroscopy; laser spectroscopy and applications; photoelectron spectroscopy; multi-photon processes.
Prerequisites:  Ch 520 or PEP 554 and PEP 509 or equivalent.

PEP 739 Theory of Relativity*
Geometrical foundations of space-time theories, geometrical objects, affine geometry, metric geometry; structure of space-time theories, symmetry, conservation laws; Newtonian mechanics; special relativity; foundations of general relativity, Mach’s principle, principle of equivalence, principle of general covariance, Einstein’s equations; solution of Einstein’s equations; experimental tests of general relativity; conservation laws in general relativity, gravitational radiation, motion of singularities; cosmology. Fall semester. Course may be taken for up to six credits.

PEP 740 The Physics of Nanostructures
Progress in the technology of nanostructure growth; space and time scales; quantum confined systems; quantum wells, coupled wells and superlattices; quantum wires and quantum dots; electronic states; magnetic field effects; electron-phonon interaction; quantum transport in nanostructures: Kubo formalism, Butikker-Landau formalism; spectroscopy of quantum dots; Coulomb blockade, coupled dots and artificial molecules; weal localization; universal conductance fluctuations; phase-breaking time; theory of open quantum systems: fluctuation-dissipation theorem; applications to quantum transport in nanostructures.
Prerequisites:  PEP 553 - 554 and PEP 661 - 662.

PEP 750 Quantum Field Theory*
This course is open to students who have taken PEP 754 or its equivalent. It concerns itself with modern field theory; such topics as Yang-Mills fields, the renormalization group and functional integration. It will concern itself with applications to both elementary particles and condensed matter physics; i.e. the theory of critical exponents. Typical text: C. Quigg, Gauge Theories of Strong, Weak and Electromagnetic Interactions.

PEP 751 Elementary Particles*
This course is open to students who have taken PEP 754 or its equivalent. It is an introduction to the theory of elementary particles. It stresses symmetries of both the strong and weak interactions. It presents a detailed study of SU(3) and the quark model as well as the Cabbibo theory of the weak interactions. Typical text: F. Close, An Introduction to Quarks and Partons.

PEP 754 Advanced Quantum Mechanics
This course is an introduction to relativistic quantum mechanics and quantum field theory. Relativistic wave equations including the Klein-Gordon equation and the Dirac equation. Commutation relation and canonical quantization of free fields. Spin and statistics of Bose and Fermi fields. Interacting quantum fields: interaction representation and S-matrix perturbation theory, Feynman diagrams and renormalization theory with applications to quantum electrodynamics. Typical texts: Advanced Quantum Mechanics by J. J. Sakurai and Quantum Field Theory by F. Mandl and G. Shaw.
Prerequisites:  PEP 653.

PEP 757 Quantum Field Theory Methods in Statistical and Many-Body Physics
Dirac notation; Transformation theory; Second quantization; Particle creation and annihilation operators; Schrödinger, Heisenberg and interaction pictures; linear response; S-matrix; density matrix; superoperators and non-Markovian kinetic equations; Schwinger action principle and variational calculus; quantum Hamilton equations; field equations with particle sources, potential and phonon sources; retarded Green’s functions; localized state in continuum and chemisorption; Dyson equation; T-matrix; impurity scattering; self-consistent Born approximation; density-of-states; Green's function matching; ensemble averages and statistical thermodynamics, Bose and Fermi distributions, Bose condensation; thermodynamic Green’s functions; Lehmann spectral representation; periodicity/antiperiodicity in imaginary time and Matsubara Fourier series/frequencies; analytic continuation to real time; multiparticle Green’s functions and equations of motion with particle-particle interactions; Hartree and Hartree-Fock approximations; collisional lifetime effects; sum-of-ladder-diagrams integral equation; nonequilibrium Green’s functions; electromagnetic current-current correlation response; exact variational relations for multiparticle Green’s functions; cumulants; linked cluster theorem; random phase approximation; perturbation theory for Green’s functions, self-energy and vertex functions by variational differential formulation; shielded potential perturbation theory; imaginary time contour ordering, Langreth algebra and the GKB Ansatz. Typical texts: Kadanoff and Baym, Quantum Statistical Mechanics, W. A. Benjamin and Horing, Advanced Quantum Mechanics for Interacting and Mesoscopic Systems. Fall semester.
Prerequisites:  PEP 242 or equivalent and a good mathematical background in linear algebra and multivariate calculus; PEP 554 will be a corequisite unless waived by instructor.

PEP 758 Coupled Quantum Field Theory Methods in Condensed Matter Physics *
Dielectric response of solid-state plasmas; random phase approximation; semiclassical and hydrodynamic models; elasmons; shielding; electron-hole plasmon Landau damping; exchange and correlation energy; atom-surface van der Waals attraction; charged particle energy loss; electrodynamic response functions; dyadic Green’s functions; dynamic, nonlocal conductivity and dielectric tensors; polaritons of compound nanostructures; coupling of light with 3D, 2D and superlattice collective modes; electron(e) - hole (h) - phonon (p) Hamiltonian for solids with e-e, h-h, e-p, h-p and e-h interactions explained; Coupled electron-hole-phonon Green’s functions of all orders and derivation of the fully-interacting equations of motion for 1-electron and 1-hole Green’s functions and for 2-electron and 2-hole Green’s functions, as well as the electron-hole Green’s function with analysis of exciton states and electron-hole scattering matrix; electron-phonon coupling effects on electron propagation and polarons; phonons of periodic lattice in the harmonic approximation, eigenvector expansion of phonon Green’s functions for monatomic and ionic diatomic lattices, acoustic and optical phonons, polarizability of a diatomic lattice; Phonon Green’s function with coupling to dynamic nonlocal electron screening, umklapp, coupled ion-electron oscillations, Bohm-Staver phonon dispersion relation; generalized shield potential approximation; electron and hole interaction operators; superfluid field operators and the Gross-Pitaevski equations; Bogoliubov approximation, superfluid Green’s functions and elementary excitations; superconductivity-BCS Theory, anomalous Green’s functions and Gorkov equations, gap, derivation of Ginzburg-Landau equations. Typical text: Horing, Advanced Quantum Mechanics for Interacting and Mesoscopic Systems; Mahan, Many-Particle Physics, Plenum Press and recommended readings. Spring semester.
Prerequisites:  PEP 757.

PEP 800 Special Topics in Physics
Topics include any one of the following: magnetohydrodynamics, quantum mechanics, general relativity, many-body problem, nuclear physics, quantum field theory, low temperature physics, diffraction theory, particle physics. Limit of six credits for the master’s degree.

PEP 801 Special Topics in Physics
One to six credits. Limit of six credits for the degree of Doctor of Philosophy.

PEP 900 Thesis in Physics
For the degree of Master of Science. Five to ten credits with departmental approval.

PEP 901 Thesis in Engineering Physics
For the degree of Master of Engineering. Five to ten credits with departmental approval.

PEP 960 Research in Physics
Original experimental or theoretical research undertaken under the guidance of the faculty of the department which may serve as the basis for the dissertation required for the degree of Doctor of Philosophy. Hours and credits to be arranged. This course is open to students who have passed the doctoral qualifying examination; a student who has already taken the required doctoral courses may register for this in the term in which s/he intends to take the qualifying examination.

* By request