Physics (PY)
Introductory, descriptive survey of stars, galaxies and cosmology, designed primarily for non-science majors. Exotic recent discoveries such as quasars, pulsars, and black holes will be included. Complements ±Ê³ÛÌý124, Solar System Astronomy. Companion laboratory course ±Ê³ÛÌý125.
GEP Natural Sciences
Typically offered in Fall and Spring
Introductory, descriptive survey of the solar system designed primarily for non-science majors, including current results from space probes, history of astronomy, and the motions of the moon, stars, and planets in the night sky. Complementary course covering stars, galaxies and cosmology (±Ê³ÛÌý123). Companion laboratory course (±Ê³ÛÌý125).
GEP Natural Sciences
Typically offered in Fall and Spring
Introduction to astronomical observing. Twelve exercises include astronomical instruments; the nature of light; Kepler's and Newton's laws of motion; the constellations, planets, binary stars, stellar clusters, and galaxies. Use of small telescopes to observe celestial objects.
GEP Natural Sciences
Typically offered in Fall and Spring
Fundamentals of physics from a conceptual rather than a mathematical viewpoint. Applications of physics to everyday phenomena and experiences. Numerous demonstrations and discovery-based laboratory. Mechanics, properties of matter, heat, sound, electricity and magnetism, light and relativity.
GEP Natural Sciences
Typically offered in Fall, Spring, and Summer
First course of three semester sequence for students majoring in physical and mathematical sciences. Calculus used throughout. Principles of classical Newtonian mechanics covered in detail.
Typically offered in Fall only
Second course of three semester sequence designed primarily for students majoring in physical and mathematical sciences. Calculus used throughout. Principles of electricity and magnetism covered in detail.
Prerequisite: ±Ê³ÛÌý201, ²Ñ´¡Ìý141, Corequisite: ²Ñ´¡Ìý241. Credit is not allowed for both ±Ê³ÛÌý202 and ±Ê³ÛÌý208 or ±Ê³ÛÌý212.
Typically offered in Spring only
Third course of three semester sequence designed primarily for students majoring in physical and mathematical sciences. Calculus is used throughout. Principles of wave optics and modern physics are covered in detail.
Typically offered in Fall only
First semester of a two-semester sequence in introductory, calculus-based physics with included laboratory experiences. This course introduces the fundamental principles of mechanics through a study of momentum, energy, and angular momentum. Other fundamental phenomena (such as oscillations and heat transfer) are also studied. Note: Some programs do not allow for more than one of ±Ê³ÛÌý201, ±Ê³ÛÌý205, or ±Ê³ÛÌý211 to be counted for credit toward degree requirements.
Corequisite: ²Ñ´¡Ìý141
GEP Natural Sciences
Typically offered in Fall, Spring, and Summer
Laboratory course to accompany the ±Ê³ÛÌý205 lecture course. A calculus-based study of mechanics, sound and heat.
Prerequisite: ²Ñ´¡Ìý141 with a grade of C- or better or ²Ñ´¡Ìý241 Placement. Co-requisite: ±Ê³ÛÌý205. ADD BOTH ±Ê³ÛÌý205 and ±Ê³ÛÌý206 TO YOUR SHOPPING CART AND THEN ENROLL SIMULTANEOUSLY
GEP Natural Sciences
Typically offered in Fall, Spring, and Summer
Second semester of a two-semester sequence in introductory, calculus-based physics with included laboratory experiences. This course introduces the fundamental aspects of electricity and magnetism and their effects in materials. Note: Some programs do not allow for more than one of ±Ê³ÛÌý202, ±Ê³ÛÌý208, or ±Ê³ÛÌý212 to be counted for credit toward degree requirements.
GEP Natural Sciences
Typically offered in Fall, Spring, and Summer
Laboratory course to accompany the ±Ê³ÛÌý208 lecture course. A calculus-based study of electricity, magnetism, optics and modern physics.
Pre-requisite: ±Ê³ÛÌý205 with grade of C- or better, ²Ñ´¡Ìý241 with grade of C- or better, ±Ê³ÛÌý206 with grade of C- or better. Co-requisite: ±Ê³ÛÌý208. ADD BOTH ±Ê³ÛÌý208 and ±Ê³ÛÌý209 TO YOUR SHOPPING CART AND THEN ENROLL SIMULTANEOUSLY
GEP Natural Sciences
Typically offered in Fall, Spring, and Summer
First semester of a two-semester introductory sequence in non-calculus physics, with laboratory. Mechanics, heat, wave motion and sound. Credit not allowed for more than one of ±Ê³ÛÌý211, ±Ê³ÛÌý201 or ±Ê³ÛÌý205
Prerequisite: ²Ñ´¡Ìý107 or 111 or 121 or 131 or 108 or 141 with a C- or better, or 480 on the SAT Subject Test in Mathematics Level 2 or the NCSU Math Skills Test, or 2 or better on an AP Calc exam. Credit is not allowed for both ±Ê³ÛÌý211 & ±Ê³ÛÌý201 or ±Ê³ÛÌý205
GEP Natural Sciences
Typically offered in Fall, Spring, and Summer
Second semester of a two-semester introductory sequence in non-calculus physics, with laboratory. Electricity, and magnetism, light, modern physics. Credit not allowed for more than one of ±Ê³ÛÌý212, ±Ê³ÛÌý202, and ±Ê³ÛÌý208
Prerequisite: ±Ê³ÛÌý211 or ±Ê³ÛÌý205. Credit is not allowed for both ±Ê³ÛÌý212 and ±Ê³ÛÌý202 or ±Ê³ÛÌý208.
GEP Natural Sciences
Typically offered in Fall, Spring, and Summer
An introductory course in scientific computing for the physical and mathematical sciences using python and other open-source tools. Using a problem-oriented approach, students will learn the basic computing skills needed to conduct scientific research and to prepare for upper-level courses in science and engineering. Topics will include algorithm development, numerical methods, elements of programming, data analysis, and data visualization.
Typically offered in Fall and Spring
Digital data acquisition and lab computers (e.g. using LabView or MatLab) are tools used in nearly all current physics research labs. By using both analysis and thorough lab experimental investigation the student will learn basic skills with electronic devices (oscilloscope, power supplies, function generator, op-amps, high & low-pass filters, feedback circuits), electronic noise (measurement and analysis), and basic circuit construction methods (such as shielding/grounding, soldering).
Typically offered in Fall and Spring
Study in experimental or analytical topics in classical and modern physics.
Typically offered in Fall, Spring, and Summer
An introduction to wave mechanics and quantum phenomena including the Schroedinger equation for simple systems, the Hamiltonian operator, the use of commutator relations, and the application of angular momentum operators. Emphasis on mathematical tools used in wave mechanics, including complex numbers, function operators, eigenvalues and eigenvectors.
Typically offered in Fall only
Introduction to the study of stars, galaxies, and the universe. Stars and stellar evolution; interstellar medium; galaxies and galaxy clusters; cosmology. Recent developments in the understanding of neutron stars, black holes, active galaxies, quasars and inflationary cosmologies.
Typically offered in Fall only
Introduction to relativity, gravitation and cosmology in accordance with Einstein's special and general theories of relativity. Flat spacetime: Minkowski metric, time dilation, length contraction, doppler effect, twin paradox, and space travel. Curved spacetime: Schwarzchild metric, black holes and event horizons, particle and light motion, Global positioning system, precession of planetary orbits. Cosmology: hubble law, expansion of the universe, Friedman-Robertson-Walker metric, big bang, cosmological redshift, dark matter and dark energy.
Typically offered in Spring only
Special Topics in theoretical, experimental, or computational physics at the intermediate undergraduate level. Course offerings vary from semester to semester. Course may be repeated if course content varies. Typically offered in Fall, Spring, and Summer.
Typically offered in Fall, Spring, and Summer
An introduction to the basic principles of quantum physics with an emphasis on selected applications to atoms, molecules, solids, nuclei and elementary particles.
Typically offered in Spring only
An introduction to the basic principles of quantum physics with an emphasis on selected applications to atoms, molecules, solids, nuclei and elementary particles.
Prerequisite: C- or better in ±Ê³ÛÌý401
Typically offered in Fall only
Major developments in modern physics: special relativity, origin of the quantum theory, atomic and molecular structure, radioactivity, properties of nuclei. Credit not allowed for both ±Ê³ÛÌý203 and ±Ê³ÛÌý407
Typically offered in Spring only
First semester of a two-semester sequence in particle and continuum mechanics at the intermediate level. Focuses on single-particle dynamics: Elementary Newtonian mechanics, harmonic oscillator, central force motion, conservation laws, motion in non-inertial frames, Coriolis and centrifugal forces, Lagrangian dynamics, Hamilton's equations.
Typically offered in Spring only
Second semester of a two-semester sequence in particle and continuum mechanics at the intermediate level. Focuses on dynamics of systems of particles and continua: center of mass, collisions, rigid bodies, inertia tensor, principal axes, stress and strain tensors, mechanical properties of fluids and solids; waves in discrete and continuum systems, coupled oscillators, normal modes, elements of special relativity.
Prerequisite: C- or better in ±Ê³ÛÌý411
Typically offered in Fall only
An introduction to statistical mechanics and thermodynamics. The statistical study of physical systems emphasizing the connection between the statistical description of macroscopic systems and classical thermodynamics. Concepts of heat, internal energy, temperature and entropy. Classical and quantum statistical distributions.
Typically offered in Spring only
First semester of a two-semester sequence. An intermediate course in electromagnetic theory using the methods of vector calculus. Electrostatic field and potential, dielectrics, solution to Laplace's and Poisson's equations, magnetic fields of steady currents.
Typically offered in Fall only
A continuation of ±Ê³ÛÌý414. Electromagnetic induction, magnetic fields in matter, Maxwell's equations, wave guides, radiation.
Prerequisite: C- o better in ±Ê³ÛÌý414
Typically offered in Spring only
Introduction to laboratory electronics and instrumentation. Experiments in mechanics; electromagnetism; electronics; optics; and atomic, nuclear, plasma and solid state physics. Senior Physics students only
Prerequisite: Senior standing, Physics Majors
Typically offered in Fall and Spring
Applications of physics to the total design and creation of an apparatus for demonstrating physics concepts. Combines discussion of group dynamics and sociology with engineering approaches to provide the supporting skills for students to work effectively in solving a physics design problem. Considerations of the design process including concept and feasibility study, systems design, detailed design, project management, cost effectiveness, along with development and evaluation of a prototype accomplished through design-team project activity.
Prerequisite: ±Ê³ÛÌý411 and Instructor consent
Typically offered in Fall only
This course studies the fundamental and recent advances of energy harvesting from two of the most abundant sources, namely solar and thermal energies. The first part of the course focuses on photovoltaic science and technology. The characteristics and design of common types of solar cells is discussed, and the known approaches to increasing solar cell efficiency will be introduced. After the review of the physics of solar cells, we will discuss advanced topics and recent progresses in solar cell technology. The second part of the course is focused on thermoelectric effect. The basic physical properties, Seebeck coefficient, electrical and thermal conductivities, are discussed and analyzed through the Boltzmann transport formalism. Advanced subject such as carrier scattering time approximations in relation to dimensionality and the density of states are studied. Different approaches for further increasing efficiencies are discussed including energy filtering, quantum confinement, size effects, band structure engineering, and phonon confinement.
P: ·¡°ä·¡Ìý302 or ·¡Ìý304 or ²Ñ³§·¡Ìý355 or ±Ê³ÛÌý407
Typically offered in Spring only
Special Topics in theoretical, experimental, or computational physics at the advanced undergraduate level. Course offerings vary from semester to semester. Course may be repeated if course content varies.
Typically offered in Fall, Spring, and Summer
Study and research in physics. Topics for experimental or theoretical investigation. Individualized/Independent Study and Research courses require a Course Agreement for Students Enrolled in Non-Standard Courses be completed by the student and faculty member prior to registration by the department.
Typically offered in Fall, Spring, and Summer
Basic principles of quantum physics with emphasis on selected applications to atoms, molecules, solids, nuclei, and elementary particles. ±Ê³ÛÌý501 - first semester in two-semester sequence in quantum mechanics; ±Ê³ÛÌý502 - second semester of sequence. Credit for both ±Ê³ÛÌý401 and ±Ê³ÛÌý501 is not allowed.
Prerequisite: Graduate Level Status in Physics or Physics Departmental Approval
Typically offered in Spring only
Basic principles of quantum physics with emphasis on selected applications to atoms, molecules, solids, nuclei and elementary particles. ±Ê³ÛÌý502 - second semester in two-semester sequence in quantum mechanics; first semester of sequence is PY501. Credit for both ±Ê³ÛÌý402 and ±Ê³ÛÌý502 is not allowed.
Prerequisite: ±Ê³ÛÌý501
Typically offered in Fall only
Introduction to nuclear and subatomic phenomena: properties of nuclear radiation and detectors, accelerators, nuclear forces and nuclear structure, elementary particles, fundamental symmetries and conservation laws.
Prerequisite: Graduate Standing
Typically offered in Fall only
Introduction to fundamental symmetries and dynamics of quarks and leptons. The Standard Model, Dirac equation, Feynman rules in QED and QCD, the Higgs mechanism and electroweak unification.
Prerequisite: (±Ê³ÛÌý401 and ±Ê³ÛÌý506 and Undergraduate Standing) or (±Ê³ÛÌý506 and Graduate Standing)
Typically offered in Spring only
This course provides in-depth knowledge of general relativity covering Einstein's equation, Schwarzschild metric, Kerr metric, Friedman-Robertson-Walker metric, Christoffel symbols, Killing vectors, Riemann curvature, and Ricci tensors. Theoretical computations are compared with data including the precession rate of the perihelion for Mercury and the deflection in the solar eclipse, the geodelic affect and the frame-dragging effect measured in the Gravity Probe B experiment.
Typically offered in Spring only
First semester of a two-semester sequence in particle and continuum mechanics at the intermediate level. Focuses on single-particle dynamics: Elementary Newtonian mechanics, harmonic oscillator, central force motion, conservation laws, motion in non-inertial frames, Coriolis and centrifugal forces, Lagrangian dynamics, Hamilton's equations.
Typically offered in Spring only
Second semester of a two-semester sequence in particle and continuum mechanics at the intermediate level. Focuses on dynamics of systems of particles and continua: center of mass, collisions, rigid bodies, inertia tensor, principal axes, stress and strain tensors, mechanical properties of fluids and solids; waves in discrete and continuum systems, coupled oscillators, normal modes, elements of special relativity.
Prerequisite: C- or better in ±Ê³ÛÌý411
Typically offered in Fall only
First semester of a two-semester sequence. An intermediate course in electromagnetic theory using the methods of vector calculus. Electrostatic field and potential, dielectrics, solution to Laplace's and Poisson's equations, magnetic fields of steady currents.
Typically offered in Fall only
A continuation of ±Ê³ÛÌý414. Electromagnetic induction, magnetic fields in matter, Maxwell's equations, wave guides, radiation.
Prerequisite: C- o better in ±Ê³ÛÌý414
Typically offered in Spring only
Physical optics with major emphasis on wave properties of light. Boundary conditions, interference and diffraction, optics of thin films, fiber optics and applications to absorption, scattering and laser operation. A background in Maxwell's equations and vector analysis required.
Prerequisite: ±Ê³ÛÌý415
Typically offered in Fall only
The quantum mechanical treatment of structure and spectra for atoms and molecules. The hydrogen atom, helium atom, multielectron atoms, selection rules, diatomic and simple polyatomic molecules and nuclear magnetic resonance spectroscopy.
Typically offered in Spring only
This course presents the application of physics principles and methods to problems in biological systems. Important biological molecules, their structures and their processes are introduced for physical scientists. Functional mechanisms are analyzed with concepts from thermodynamics, statistical mechanics, fluid mechanics, and electrostatics. Modern experimental methods and computational approaches to molecular and cellular level biological phenomena are emphasized.
Prerequisite: ±Ê³ÛÌý413 or Graduate Standing
Typically offered in Spring only
Computational approach to solving physics problems using standard software relevant for physicists. Electrostatic potentials, data analysis, Monte Carlo simulations, Fourier optics, particle orbits, Schrodinger's equation. Examples and assignments for each topic are chosen to complement other physics courses.
Prerequisite: °ä³§°äÌý112 or equivalent; Corequisite: ±Ê³ÛÌý401 and Graduate Standing or departmental permission
Typically offered in Fall only
Concepts in plasma physics, basics of thermonuclear reactions; charged particle collisions, single particle motions and drifts, radiation from plasmas and plasma waves, fluid theory of plasmas, formation and heating of plasmas, plasma confinement, fusion devices and other plasma applications.
Typically offered in Fall only
This course expands on the treatment of plasmas as a system of coupled fluids and introduces the foundations of plasma kinetic theory. Derivation of the plasma kinetic equation and the Vlasov equation serve as the starting point to introduce the kinetic study of plasma systems. From this introduction of the governing equations for full kinetic treatment, methods for analyzing plasma response to electromagnetic and electrostatic perturbations using the linearized Vlasov model for uncorrelated plasmas are introduced. Kinetic stability of Vlasov plasmas is introduced and the Nyquist method is used to determine conditions for kinetic stability. The concept of correlated plasmas is then introduced through the introduction of reduced distribution functions and the BBGKY heirarchy. Finally, simple correlated systems and the Liouville model for two-system correlation is covered to look at the impact of particle correlation due to collisions and coulomb interaction.
Prerequisite: ±··¡Ìý528
Typically offered in Spring only
Basic physics necessary to investigate, from observational data, internal conditions and evolution of stars. This includes the formation and structure of spectral lines, methods of energy generation and transport, stellar structure, degeneracy, white dwarfs, and neutron stars.
Typically offered in Spring only
Basic considerations of crystalline solids, metals, conductors and semiconductors.
Prerequisite: C- or better in ±Ê³ÛÌý401; Graduate standing or departmental permission
Typically offered in Spring only
Polymer microstructures, solutions, physical states (including amorphous polymers, crystalline polymers, polymer melts, melting of polymers, glass-transition, and other transitions), polymer blends, mechanical properties, and viscoelasticity and flow, multicomponent polymer systems, and modern polymer topics. The physics of polymer fibers. Graduate standing or permission of instructor.
Typically offered in Fall only
First semester (mechanics) of a two-semester sequence intended to broaden and deepen the knowledge of high school physics teachers about introductory-level physics from a contemporary point of view. The course includes an introduction to computational physics. Departmental permission is required: the course is normally restricted to in-service high-school physics teachers.
Typically offered in Spring only
Second semester (electricity and magnetism) of a two-semester sequence intended to broaden and deepen the knowledge of high-school physics teachers of introductory-level physics from a contemporary point of view. The course includes an introduction to computational physics. Departmental permission is required: the course is normally restricted to in-service high-school physics teachers. The ±Ê³ÛÌý581 prerequisite may be waived with strong background in physics and mathematics.
Typically offered in Fall only
This course studies the fundamental and recent advances of energy harvesting from two of the most abundant sources, namely solar and thermal energies. The first part of the course focuses on photovoltaic science and technology. The characteristics and design of common types of solar cells is discussed, and the known approaches to increasing solar cell efficiency will be introduced. After the review of the physics of solar cells, we will discuss advanced topics and recent progresses in solar cell technology. The second part of the course is focused on thermoelectric effect. The basic physical properties, Seebeck coefficient, electrical and thermal conductivities, are discussed and analyzed through the Boltzmann transport formalism. Advanced subject such as carrier scattering time approximations in relation to dimensionality and the density of states are studied. Different approaches for further increasing efficiencies are discussed including energy filtering, quantum confinement, size effects, band structure engineering, and phonon confinement.
P: ·¡°ä·¡Ìý302 or ·¡Ìý304 or ²Ñ³§·¡Ìý355 or ±Ê³ÛÌý407
Typically offered in Spring only
Investigations in physics under staff guidance. May consist of literature reviews, experimental or theoretical projects, or special-topics lectures. Credits Arranged
Typically offered in Fall, Spring, and Summer
Investigations in physics under staff guidance. May consist of literature reviews, experimental or theoretical projects, or special-topics lectures. Credits arranged
Typically offered in Fall, Spring, and Summer
Reports on topics of current interest in physics. Several sections are offered so that students with common research interests may be grouped together.
Typically offered in Fall and Spring
Investigations in physics under staff guidance. May consist of literature reviews, experimental or theoretical projects, or special topics lectures. Credits Arranged.
Typically offered in Fall and Spring
Instruction in research and research under the mentorship of a member of the Graduate Faculty.
Prerequisite: Master's student
Typically offered in Spring only
Thesis Research
Prerequisite: Master's student
Typically offered in Fall, Spring, and Summer
For students who have completed all credit hour requirements and full-time enrollment for the master's degree and are writing and defending their thesis. Credits Arranged
Prerequisite: Master's student
Typically offered in Summer only
Introduction to relativistic quantum theory of Dirac particles and the positron. Other topics including second quantization technique and its application to many-body problems, radiation theory, and quantization of the electromagnetic field.
Prerequisite: ±Ê³ÛÌý782
Typically offered in Fall only
A general propagator treatment of Dirac particles, photons, and scalar and vector mesons. Applications of Feynman graphs and rules illustrating basic techniques employed in the treatment of electromagnetic, weak, and strong interactions. Renormalization theory, the effects of radiative corrections, and aspects of the general Lorentz covariant theory of quantized fields.
Prerequisite: ±Ê³ÛÌý711
Typically offered in Spring only
Basic elements of kinetic theory and equilibrium statistical mechanics, both classical and quantum; applications of the techniques developed to various ideal models of noninteracting particles. The final exam is the Department qualifying exam for statistical mechanics.
Typically offered in Spring only
A continuation of ±Ê³ÛÌý721, with emphasis on the static and dynamic properties of real (interacting) systems. Topics including equilibrium theory of fluids and linear response theory of time-dependent phenomena.
Prerequisite: ±Ê³ÛÌý721
Typically offered in Fall only
The properties of semiconductors, superconductors, magnets, ferroelectrics, and crystalline defects and dislocations.
Prerequisite: ±Ê³ÛÌý552
Typically offered in Fall only
Fundamental concepts and formulations, including interpretation and techniques. Application of theory to simple physical systems, such as the free particle, the harmonic oscillator, the particle in a potential well, and central force problems. Other topics include approximation methods, identical particles and spin, transformation theory, symmetries and invariance, and an introduction to quantum theory of scattering and angular momentum.
Typically offered in Fall only
Fundamental concepts and formulations, including interpretation and techniques, and the application of theory to simple physical systems, such as the free particle, the harmonic oscillator, the particle in a potential well, and central force problems. Other topics include approximation methods, identical particles and spin, transformation theory, symmetries and invariance, and an introduction to the quantum theory of scattering and angular momentum. The final exam is the Department qualifying exam for quantum mechanics.
Prerequisite: ±Ê³ÛÌý781 and Graduate standing
Typically offered in Spring only
Introduction to theoretical physics in preparation for advanced study. Emphasis on classical mechanics, special relativity, and the motion of charged particles. Topics include variational principles, Hamiltonian dynamics, canonical transformation theory, structure of the Lorentz group, and elementary dynamics of unquantized fields. The final exam is the Department qualifying exam for classical mechanics.
Typically offered in Fall only
This is the first semester of a two-semester sequence focusing on electrostatics. Topics include establishing the physical basis of Maxwell's Equations; image-charge, series-expansion, and Green-function methods for determining electrostatic potentials and solving boundary-condition problems in one, two, and three dimensions (mathematics includes Bessel functions and spherical harmonics); dielectric response theory in linear and nonlinear limits; Cauchy theorem, causality, Kramers-Kronig relations, and sum rules; Green functions and response theory in the time domain; inhomogeneous materials and plasmonics; magnetostatics. The final exam is the Department qualifying exam for electricity and magnetism.
Prerequisite: ±Ê³ÛÌý415; Graduate standing
Typically offered in Fall only
This is the second semester of a two-semester series, focusing on time-dependent phenomena. Building on Maxwell's Equations, topics include conduction, induction, and magnetodynamics; physics of transformers, motors, and generators; plane waves: propagation in homogeneous and anisotropic media, coherent and incoherent superposition (short-pulse optics, Stokes parameters); wave physics at planar interfaces: reflection, transmission, multilayer phenomena, and plasmonics; waveguides including optical fibers-and energy transfer; radiation and scattering: Green functions, retardation physics, Lienard-Wiechert potentials; interference (constructive and destructive), shock waves; diffraction: Fresnel and Fraunhofer diffraction, Gaussian beams (photon spin, orbital angular momentum, topological charge); special relativity: Lorentz transformations, 4-vectors, nominal paradoxes, synchrotron radiation, and tensor formulation.
Prerequisite: ±Ê³ÛÌý785 and Graduate Standing
Typically offered in Spring only
Reports on topics of current interest in physics. Several sections offered so that students with common research interests may be grouped together.
Typically offered in Fall and Spring
Investigations in physics under staff guidance. May consist of literature reviews, experimental or theoretical projects or special topics lectures. Credits Arranged
Typically offered in Fall and Spring
Teaching experience under the mentorship of faculty who assist the student in planning for the teaching assignment, observe and provide feedback to the student during the teaching assignment and evaluate the student upon completion of the assignment.
Prerequisite: Doctoral student
Typically offered in Spring only
Instruction in research and research under the mentorship of a member of the Graduate Faculty.
Prerequisite: Doctoral student
Typically offered in Spring only
Dissertation Research
Prerequisite: Doctoral student
Typically offered in Fall, Spring, and Summer
For graduate students whose programs of work specify no formal course work during a summer session and who will be devoting full time to thesis research.
Prerequisite: Doctoral student
Typically offered in Summer only
For students who have completed all credit hour requirements, full-time enrollment, preliminary examination, and residency requirements for the doctoral degree, and are writing and defending their dissertations.
Prerequisite: Doctoral student
Typically offered in Fall, Spring, and Summer