PHYS 5100 Current Topics In Physics (1 semester hour) Study of current
research topics in physics. (P/F grading, may be repeated for credit.) (1-0) R
PHYS 5V49 Special Topics In Physics (1-6 semester hours) Topics may vary
from semester to semester. (May be repeated for credit to a maximum of 9
hours.) ([1-6]-0) R
PHYS 5283 Plasma Technology Laboratory (2 semester hours) Laboratory
will provide a �hands-on� experience to accompany PHYS 5383. Topics to include:
vacuum technology [pumps, gauges, gas feed], plasma uses [etch, deposition,
lighting and plasma thrusters] and introductory diagnostics. Corequisite: PHYS
5383, Recommended Co-requisite: PHYS 7171, Cross-listed with: EE 5283. (0-6) R
PHYS 5304 Proposal And Report Preparation (3 semester hours) A
discussion of techniques for writing successful proposals and formal reports.
Topics include types of proposals, the importance of logical organization and
outlines, interpretation of RFPs, preparation and submission of unsolicited
proposals, elements of writing style, statements of work and milestones,
estimation of project timelines, and the importance of accurate cost estimates.
(3-0) R
PHYS 5305 Monte Carlo Simulation Method and its Application (3 semester
hours) An introductory course on the method of
PHYS 5411 Classical Mechanics (4 semester hours)
A course that aims to provide intensive training in problem
solving.� Rigorous survey of Newtonian
mechanics of systems, including its relativity principle and applications to
cosmology;� the ellipsoid of inertia and
its eigenstructure, with applications, Poinsot's theorem;� Euler's equations, spinning tops;� Lagrangian and Hamiltonian formalism with
applications; chaos, small oscillations, velocity dependent potentials, Lagrange
multipliers and corresponding constraint forces, canonical transformations,
Lagrange and Poisson brackets, Hamilton-Jacobi theory.(4-0) Y
PHYS 5413 Statistical Physics (4 semester hours)
Phase space, distribution functions and density matrices; Microcanonical,
canonical and grand canonical ensembles; Partition functions; Principle of
maximum entropy; Thermodynamic potentials and laws of thermodynamics; Classical
and quantum ideal gases; Non-interacting magnetic moments; Phonons and specific
heat of solids; Degenerate electron gas, its specific heat and magnetism;
Statistics of carriers in semiconductors; Bose-Einstein condensation;
Black-body radiation; Boltzmann transport equation and H-theorem; Relaxation
time and conductivity; Brownian motion, random walks and Langevin equation;
Einstein's relation; Fluctuations in ideal gases; Linear response and
fluctuation-dissipation theorem; Virial and cluster expansions, van der Waals
equation of state; Poisson-Boltzmann and Thomas-Fermi equations; Phases, phase
diagrams and phase transitions of the first and second order; Lattice spin
models; Ordering, order parameters and broken symmetries; Mean-field theory of
ferromagnetism; Landau and Ginzburg-Landau theories; Elements of modern theory
of critical phenomena. (4-0) T
PHYS 5317 Atoms, Molecules And Solids I (3 semester hours) Core course
for Applied Physics Concentration. Fundamental physical description of
microsystems starting with the need for quantum mechanics and proceeding
through the application of quantum mechanics to atomic systems. Emphasis will
be on a physical understanding of the principles which apply to technologically
important devices. Computer simulations will be used to focus the student on
the important physical principals and not on detailed exact solutions to
differential equations. Topics covered include: Justification for quantum
mechanics, application of quantum mechanics to one-electron problems,
application to multi-electron problems in atomic systems. Prerequisite:
Undergraduate multi-variable calculus and two semesters of calculus based
physics. (3-0) Y
PHYS 5318 Atoms, Molecules And Solids II (3 semester hours) Core course
for Applied Physics Concentration. Application of quantum mechanics to
molecules and solids. Topics in solids include optical, thermal, magnetic and
electric properties, impurity doping and its effects on electronic properties,
superconductivity, and surface effects. Various devices, such as, transistors,
FET�s, quantum wells, detectors and lasers will also be discussed. PHYS 5317,
or equivalent. (3-0) Y
PHYS 5321 Experimental Operation And Data Collection Using Personal
Computers (3 semester hours) Computer interfacing to physical experiments
using high level interface languages and environments. The student will have
the opportunity to learn how to develop data acquisition software using LabView
and LabWindows/CVI as well as how to write drivers to interface these languages
to devices over the general purpose interface buss (GPIB). A laboratory is
provided for hands-on training in these devices. (3-0) R
PHYS 5422 Electromagnetism II (4 semester hours) Fields and Potentials,
Gauge transformations and the Wave Equation
Electromagnetic waves in unbounded media � non-dispersive
and dispersive media
Boundary conditions at interfaces. Solutions to the wave
equation in rectangular cylindrical and spherical coordinates. Electromagnetic
waves in bonded media � waveguides and resonant cavities. Radiating systems �
electric and magnetic dipole radiation, electric quadrupole radiation.
Fundamentals of scattering and scalar diffraction.
Lorentz transformation and covariant forms for Maxwell�s
equations. Radiation from moving charges � Synchrotron, Cherenkov and
Bremstrahlung Radiation Pre-requisite PHYS 5421 or equivalent. (4-0) Y
PHYS 5323 Virtual Instrumentation with Biomedical
Clinical and Healthcare Applications (3 semester hours) The application of
the graphical programming environment of LabView will be demonstrated with
examples related to the health care industry. Examples will be provided to
highlight the use of the personal computer as a virtual instrument in the
clinical and laboratory environment. A laboratory is provided for hands-on
training to augment the lecture. (3-0)R
PHYS 5324 Computer Interfacing And Data Acquisition (3 semester hours)
Hardware and software operation of various devices which interface computers
into physical experiments. The student will have the opportunity to learn how
to program personal computers using the C and C++ programming language for data
acquisition and control of experiments. The operation of digital input and
output devices, analog to digital converters, digital to analog converters,
counters, and timers will be discussed as well as the operation of intelligent
controllers over the general purpose interface buss (GPIB). A laboratory is
provided for hands-on training in these devices.(3-0) Y
PHYS 5351 Basic Aspects and Practical Applications of Spectroscopy. (3
semester hours) Atomic and Molecular spectroscopy has played a pivotal role in
our understanding of atomic structure and in the formulation of quantum
mechanics. The numerous and rapidly growing field of spectroscopic applications
spans many disciplines. Topics included in course: atomic structure; spin-orbit
interactions and coupling; influence of applied fields; molecular bands,
vibrations and rotations; selection rules and intensities. Laboratory exercises
focus on acquisition and interpretation of spectroscopic signatures from active
plasmas and on spectroscopic techniques suitable for surface analysis. (2-3) R
PHYS 5361 Fourier Optics (3 semester hours) Theory of diffraction and
coherence; experiments with Gaussian beams and modes. Cross-listed with: EE 6309
(3-0) R
PHYS 5367 Photonic Devices (3 semester hours) Basic principles of
Photophysics of Condensed Matter with application to devices. Topics covered
include photonic crystals, PBG systems, low threshold lasers, photonic
switches, Super-prisms and super-lenses. Photodetectors and photocells. (3-0) R
PHYS 5369 Special Topics in Applied Physics (3 semester hours) Topics
may vary from semester to semester. (May be repeated for credit up to a maximum
of 9 hours.) (3-0) R
PHYS 5371 Solid State Physics (3 semester hours) Symmetry description of
crystals, bonding, properties of metals, electronic band theory, thermal
properties, lattice vibration, elementary properties of semiconductors.
Prerequisites: PHYS 5400 and 5421 or equivalent. (3-0) Y
PHYS 5372 Solid State Devices (3 semester hours) Basic concepts of solid
state physics with application to devices. Topics covered include semiconductor
homojunctions and heterojunctions, low dimensional physics, one and two
dimensional electron gases, hot electron systems, semiconductor lasers, field
effect and heterojunction transistors, microwave diodes and infrared and solar
devices. Prerequisite: PHYS 5318 (3-0) T
PHYS 5375 Electronic Devices Based On Organic Solids (3 semester hours)
Solid state device physics based on organic condensed matter structures,
including: OLEDs (organic light emitting diodes), organic FETs, organic lasers,
plastic photocells, molecular electronic chips. (3-0) R
PHYS 5376 Introduction to Materials Science The basic concepts of
physics and chemistry that a materials scientist needs to understand internal
interactions within materials. Emphasis is placed on the bio-physical aspects
of materials. Cross-listed with: EE 7v82
PHYS 5381 Space Science (3 semester hours) Introduction to the dynamics
of the middle and upper atmospheres, ionospheres and magnetospheres of the
earth and planets and the interplanetary medium. Topics include: turbulence and
diffusion, photochemistry, aurorae and airglow, space weather and the global
electric circuit. (3-0) T
PHYS 5382 Space Science Instrumentation (3 semester hours) Design,
testing and operational criteria for space flight instrumentation including
retarding potential analyzers, drift meters, neutral and ion mass
spectrometers, auroral particle spectrometers, fast ion mass spectrometers,
Langmuir probes, and optical spectrometers; ground support equipment; microprocessor
design and operations. (3-0) R
PHYS 5383 Plasma Technology (3 semester hours) Hardware oriented study
of useful laboratory plasmas. Topics will include vacuum technology, gas
kinetic theory, basic plasma theory and an introduction to the uses of plasmas
in various industries. Cross-listed with: EE 5383 (3-0) R
PHYS 5385 Natural And Anthropogenic Effects On The Atmosphere (3
semester hours) An examination of the physical, chemical and electrical effects
on the atmosphere and clouds due to varying solar photon and solar wind inputs;
and of the physical and chemical effects on ozone and atmospheric temperature
following anthropogenic release of CFC�s and greenhouse gases into the
atmosphere. Suitable for Science Education and other non-physics majors. (3-0)
R
PHYS 5391 Relativity I (3 semester hours) Mach�s principle and the
abolition of absolute space; the principle of relativity; the principle of
equivalence; basic cosmology; four-vector calculus; special relativistic
kinematics, optics, mechanics, and electromagnetism; basic ideas of general
relativity. (3-0) T
PHYS 5392 Relativity II (3 semester hours) Tensor calculus and
Riemannian geometry; mathematical foundation of general relativity; the crucial
tests; fundamentals of theoretical relativistic cosmology; the Friedmann model
universes; comparison with observation. (Normally follows PHYS 5391.) (3-0) T
PHYS 5395 Cosmology (3 semester hours) The course is
an overview of contemporary cosmology including: cosmological models of the
universe and their parameters; large scale structure of the universe; dark
matter; cosmological probes and techniques such as gravitational lensing,
cosmic microwave background radiation, and supernova searches; very early
stages of the universe; dark energy and recent cosmic acceleration. (3-0) T
PHYS 5401 Mathematical Methods Of Physics I (4 semester hours) Vector
analysis and calculus, general curvilinear coordinates, tensor analysis, linear
and matrix algebra, group theory, infinite series, and functions of a complex
variable (including contour integration and the residue theorem). (4-0) Y
PHYS 5402 Mathematical Methods of Physics II (4 semester hours) Ordinary
and partial differential equations, Sturm-Liouville theory of differential
equations and orthogonal functions, special functions including Bessel,
Legendre, Laguerre, Hermite, Chebyshev, and Hypergeometric functions, the Gamma
and Beta functions, Fourier series, integral transformations, and Green�s
functions. (4-0) Y
PHYS 5406 Mathematical Methods of Applied Physics (4 semester hours)
Elements of applied mathematics relevant to real world applications, including
vector calculus, linear algenbar, transforms, differential equations, and
numerical solutions of differential equations. (4-0) Y
PHYS 5416 Applied Numerical Methods (4 semester hours) Core course for
Applied Physics Concentration. A hands-on approach to the development and use
of computational tools in solving problems routinely encountered in upper level
applied physics and engineering. Main topics include curve fitting and
regression analysis, significance tests, principles of numerical modeling,
verification and validation of numerical algorithms, and nonlinear model
building. Examples from real world applications will be presented and discussed
to illustrate the appropriate use of numerical techniques. Prerequisites: PHYS
5401 or equivalent, and proficiency in a programming language. (4-0) Y
PHYS 5421 Electromagnetism I (4 semester hours) Electrostatic boundary
value problems, uniqueness theorems, method of images, Green�s functions,
multipole potentials, Legendre polynomials and spherical harmonics, dielectric
and magnetic materials, magnetostatics, time-varying field and Maxwell�s
equations, energy and momentum of the field, Lienard-Wiechert potentials,
electromagnetic radiation, polarization, refraction and reflection at plane
interfaces. (4-0) Y
PHYS 5425 Applied Electromagnetics I (4 semester hours) Boundary value
problems, method of images, Green�s functions, multipole potentials, Bessel
Functions, Legendre polynomials and spherical harmonics, dielectric and
magnetic materials, magnetostatics, time-varying field and Maxwell�s equations,
energy and momentum of the field, electromagnetic radiation, polarization,
refraction and reflection at plane interfaces.(4-0)Y
PHYS 5426 Applied Electromagnetics II (4 semester hours) Course content
emphasizes advanced concepts in applied electromagnetism, including microwaves,
magnetrons, propagation in anisotropic media, elementary scattering theory,
antenna systems, waveguides, and optic fibers. Examples of real physical
systems will be provided and examined. Software simulations will be used to
study specific devices and applications. Prerequisites: Phys 5425 and Phys 5401.
(4-0) Y
PHYS 6283 Plasma Physics Laboratory (2 semester hours) Laboratory will
provide a �hands-on� experience to accompany PHYS 6383. Experiments will
include measurements of fundamental plasma properties and understanding of
important plasma diagnostics. Corequisite: PHYS 6383, Recommended Co-requisite:
PHYS 7171, Cross-listed with: EE 6283. (0-6) T
PHYS 6400 Quantum Mechanics I (4 semester hours )
Dirac formalism, kets, bras,
operators and position, momentum, and matrix representations, change of basis,
Stern-Gerlach experiment, observables and uncertainty principle, translations,
wave functions, time evolution, the Schr�dinger and Heisenberg pictures, simple
harmonic oscillator, wave equation, WKB approximation, rotations, angular
momentum, spin, Clebsch-Gordan coefficients, perturbation theory, variational
methods. Prerequisite: PHYS 5411 or consent of the instructor. (4-0) YPHYS 6401
Quantum Mechanics II (4 semester hours)
Non-relativistic many-particle systems and their second
quantization description with creation and annihilation operators; Interactions
and Hartree-Fock approximation, quasi-particles; Attraction of fermions and
superconductivity; Repulsion of bosons and superfluidity; Lattice systems,
classical fields and canonical quantization of wave equations; Free
electromagnetic field, gauges and quantization: photons; Coherent states;
Interaction of light with atoms and condensed systems: emission, absorption and
scattering; Vacuum fluctuations and Casimir force; Elements of relativistic
quantum mechanics: Klein-Gordon and Dirac equations; Particles and
antiparticles; Spin-orbit coupling; Fine structure of the hydrogen atom; Micro-causality
and spin-statistics theorem; Non-relativistic scattering theory: scattering
amplitudes, phase shifts, cross-section and optical theorem; Born series;
Inelastic and resonance scattering; Perturbative analysis of the interacting
fields: Time evolution and interaction representation, S-matrix and Feynman
diagrams; Simple scattering processes; Dyson�s equation, self-energy and
renormalization. �Prerequisite: PHYS 6400.
(4-0) Y
PHYS 6303 Applications Of Group Theory In Physics (3 semester hours)
Group representation theory and selected applications in atomic, molecular and
elementary-particle physics. Survey of abstract group theory and matrix representations
of SU(2) and the rotation group, group theory and special functions, the role
of group theory in the calculation of energy levels, matrix elements and
selection rules, Abelian and non-Abelian gauge field theories, the Dirac
equation, representations of SU(3), and the Standard Model of
elementary-particle physics. Prerequisite: PHYS 5401. (3-0) Y
PHYS 6309 Special Topics In Mathematical Methods of Physics (3 semester
hours) Topics vary from semester to semester. (May be repeated for credit to a
maximum of 9 hours.) (3-0) R
PHYS 6311 Relativistic Quantum Field Theory I (3 semester hours)
Classical fields; relativistic quantum mechanics of spin 0 and 1/2 particles;
Klien-Gordon and Dirac equations; fundamentals of quantum field theory and
quantum electrodynamics; second quantization; spin and statistics; covariant
perturbation theory; Mott scattering; annihilation and Compton scattering;
Feynman graphs; Moller scattering; mass and charge renormalization. (Normally
follows PHYS 6300 or 6301.) (3-0) R
PHYS 6312 Relativistic Quantum Field Theory II (3 semester hours)
Introduction to Gauge Theories, Weinberg-Salam model of electroweak
interactions, spontaneous symmetry breaking, introduction to QCD,
renormalization theory. Prerequisite: PHYS 6311. (3-0) R
PHYS 6313 Elementary Particles (3 semester hours) Elementary particles
and their interaction; classification of elementary particles; fermions and
bosons; particles and antiparticles; leptons and hadrons; mesons and baryons;
stable particles and resonances; hadrons as composites of quarks and
anti-quarks; fundamental interactions and fields; electromagnetic,
gravitational, weak and strong interactions; conservation laws in fundamental
interactions; parity, isospin, strangeness, G-parity; helicity and chirality;
charge conjugation and time reversal; strong reflection and CPT theorem; gauge
invariance; quarks and gluons; discovery of c, b and t quarks and the W+ and Z�
particles; recent discoveries. (Normally follows PHYS 6300 or 6301.) (3-0) T
PHYS 6314 High Energy Physics (3 semester hours) Electromagnetic and
nuclear interactions of particles with matter; particle detectors; accelerators
and colliding beam machines; invariance principles and conservation laws;
hadron-hadron interactions; static quark model of hadrons; weak interactions;
lepton-quark interactions; the parton model of hadrons; fundamental
interactions and their unification; generalized gauge invariance; the
Weinberg-Salam Model and its experimental tests: quantum chromo-dynamics;
quark-quark interactions; grand unification theories; proton decay, magnetic
monopoles, neutrino oscillations and cosmological aspects; supersymmetries.
(Normally follows PHYS 6313.) (3-0) T
PHYS 6316 High Energy Physics Instrumentation (3 semester hours) High
energy accelerators and colliders; electromagnetic interaction of charged
particles and photons with matter; nuclear interactions with matter; particle
counters, track detectors, show detectors and calorimeters; data acquisition,
trigger, and data handling and analysis systems; design and construction of
complex high-energy physics detectors. (3-0) T
PHYS 6318 High Energy Accelerators (3 semester hours) Cyclic
accelerators (synchrotrons); proton and electron synchrotrons; focusing and
beam stability; linear accelerators (linacs); colliders; hadron and electron
colliders; cooling in pp colliders; accelerator complexes. (3-0) R
PHYS 6339 Special Topics In Quantum Electronics (3 semester hours)
Topics vary from semester to semester. (May be repeated for credit to a maximum
of 9 hours.) (3-0) R
PHYS 6341 Nuclear Physics I: The Principles Of Nuclear Physics (3
semester hours) Atomic physics; atomic spectra, x-rays and atomic structure.
The constitution of the nucleus; isotopes, natural radioactivity, artificial
nuclear disintegration and artificial radioactivity; alpha-, beta-, and
gamma-decay; nuclear reactions, nuclear forces and nuclear structure. Nuclear
models, neutron physics and nuclear fission. (3-0) T
PHYS 6342 Nuclear Physics II: Physics And Measurement Of Nuclear Radiations
(3 semester hours) Interaction of nuclear radiation with matter;
electromagnetic interaction of electrons and photons; nuclear interactions.
Operation and construction of counters and particle track detectors; electronic
data acquisition and analysis systems. Statistical evaluation of experimental
data. (3-0) T
PHYS 6349 Special Topics In High Energy Physics (3 semester hours)
Topics vary from semester to semester. (May be repeated for credit to a maximum
of 9 hours.) (3-0) R
PHYS 6353 Atomic And Molecular Processes (3 semester hours) Study of
theory and experimental methods applied to elastic scattering, excitation and
ionization of atoms and molecules by electron and ion impact, electron
attachment and detachment, and charge transfer processes. (3-0) R
PHYS 6366 Optics of Photonic Band Gap Nanostructures (3 semester hours)
Optical properties of periodic dielectric and metallic structures. Basics of
photonic band gap (PBG) formation. Critical contrast for complete PBG. Density
of states in PBG systems. Intragap states and light localisation phenomena.
Tunable PBG: solvatochromism, PBG electro-tuning by liquid crystals. PBG in
dispersive media:Bragg-polaritons Plasmon gaps in metallic photonic crystals.
Examples of 3-d PBG systems: inverted opals, Si-PBG chips. Inhibition of
spontaneous emission in PBG. Low threshold PBG-lasing in �Left-handed�
electromagnetic structures with negative refraction. (3-0) R
PHYS 6369 Special Topics In Optics (3 semester hours) Topics vary from
semester to semester. (May be repeated for credit to a maximum of 9 hours.)
(3-0) R
PHYS 6371 Advanced Solid State Physics (3 semester hours) Continuation
of PHYS 5371, transport properties of semiconductors, ferroelectricity and
structural phase transitions, magnetism, superconductivity, quantum devices,
surfaces. Prerequisite: PHYS 5371 or equivalent. (3-0) R
PHYS 6372 Physical Materials Science (3 semester hours) Advanced
concepts of Materials Science. New directions in fabrication routes and
materials design, such as biologically-inspired routes to electronic materials.
Advanced materials and device characterization . Prerequisite: PHYS 5376 or
equivalent. (3-0) R
PHYS 6374 Optical Properties Of Solids (3 semester hours) Optical
response in solids and its applications. Lorentz, Drude and quantum mechanical
models for dielectric response function. Kramers-Kronig transformation and sum
rules considered. Basic properties related to band structure effects, excitons
and other excitations. Experimental techniques including reflectance,
absorption, modulated reflectance, Raman scattering. Prerequisite: PHYS 5371 or
equivalent. (3-0) T
PHYS 6376 Electronics and Photonics of Molecular and Organic Solids (3
semester hours) Electronic energy bands in molecular solids and conjugated
polymers. Elementary excitations: Frenkel, Wannier and charge transfer
excitons. Polarons, bipolarons and solitons. Mobility of excitons and charge
carriers, photoconductivity. Charge generation and recombination,
electroluminescense, photovoltaic phenomena. Spin selective magnetic effects on
excitons and carriers. Superconductivity: granular SC, and field induced SC in
organic FETs. (3-0) R
PHYS 6377 Physics of Nanostructures: Carbon nanotubes, Fullerenes, Quantum
wells, dots and wires (3 semester hours) Electronic bands in low
dimensions. 0-d systems: fullerenes and quantum dots. Optical properties,
superconductivity and ferromagnetism of fullerides. 1-d systems: nano-wires and
carbon nanotubes (CNT). Energy bands of CNTs: chirality and electronic
spectrum. Metallic versus semiconducting CNT: arm-chair, zigzag and chiral
tubes. Electrical conductivity and superconductivity of CNTs, thermopower.
Electromechanics of SWCNT: artificial muscles. Quantum wells, FETs and organic
superlattices: confinement of electrons and excitons. Integer and fractional
quantum Hall effect (QHE). (3-0) R
PHYS 6379 Special Topics In Solid State Physics (3 semester hours)
Topics vary from semester to semester. (May be repeated for credit to a maximum
of 9 hours.) Cross-listed with: EE 7v82(3-0) R
PHYS 6383 Plasma Science (3 semester hours): Theoretically oriented
study of plasmas. Topics to include: fundamental properties of plasmas,
fundamental equations (kinetic and fluid theory, electromagnetic waves, plasma
waves, plasma sheaths) plasma chemistry and plasma diagnostics. Prerequisite:
PHYS 5421 or equivalent. Cross-listed with: EE 6383 (3-0) T
PHYS 6385 Atmospheres and Ionospheres (3 semester hours) Characteristics
of the neutral upper atmospheres of the earth and planets; including dynamics
and structure. Topics include: photochemistry; tides, winds and waves; eddy and
molecular diffusion; and magnetospheric energy inputs. Prerequisite: PHYS 5381.
(3-0) R
PHYS 6388 Ionospheric Electrodynamics (3 semester hours) Generation of
electric fields in the earth�s ionosphere. The role of internal dynamos and
external generators from the interaction of the earth with the solar wind.
Satellite and ground-based observations of ionospheric phenomena such as ExB
drift, the polar wind and plasma instabilities. Prerequisites: PHYS 5421, PHYS
6383 (3-0) R
PHYS 6V59 Special Topics In Atomic Physics (1-3 semester hours) Topics
vary from semester to semester. (May be repeated for credit to a maximum of 9
hours.) ([1-3]-0) R
PHYS 6389 Special Topics In Space Physics (3 semester hours) Topics will
vary from semester to semester. (May be repeated for credit to a maximum of 9
hours.) (3-0) R
PHYS 6399 Special Topics In Relativity (3 semester hours) Topics vary
from semester to semester. (May be repeated for credit to a maximum of 9
hours.) (3-0) R
PHYS 7V10 Internal Research (3-6 Semester Hours) On campus research for
Masters in Applied Physics. May be repeated for credit. ([3-6]-0)
PHYS
PHYS 7171 Current Topics in Plasma Physics (1 semester hour): Discussion
of current literature on plasma processing and general plasma physics;
applications, diagnostics, sources, chemistry and technology. (May be repeated
up to three times for credit.) Prerequisite or co-requisite: PHYS 6383 Cross-listed
with: EE 7171 (1-0)
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PHYS 8398 Thesis (3 semester hours) (May be repeated for credit.) (3-0)
R
PHYS 8399 Dissertation (3 semester hours) (May be repeated for credit.)
(3-0) S