BS in Physics
MS in Physics
PhD in Physics
MS in Physics
For more information, contact:
Dr. Teviet Creighton
Graduate program coordinator
Department of Physics and Astronomy
30-Hour Thesis/Non Thesis Program
Two options are available for the degree plan leading to the Master of
Science in Physics, and the candidate must declare one of the options at the time
of admission. Both options require 30 semester credit hours for successful
Information related to the application procedure and deadlines is available
through the Office of Graduate Studies (www.utb.edu/graduatestudies). All
admission requirements as described in the Graduate Catalog remain in effect.
Specific criteria for unconditional admission in the M.S. Physics program are
- Online Application
- Undergraduate GPA of 3.0
- GRE General test scores (www.ets.org)
- The scores must be sent by ETS directly to the University. The ETS code for the
University of Texas at Brownsville is 6588.
- To provide some guidance to prospective applicants, the middle 50 percent of
GRE-Quantitative scores for students admitted unconditionally in Fall 2010
ranged from 760 to 800.
- Official transcripts from all previoiusly obtained college-level degrees.
- Two letters of recommendation from people familiar with the applicant's
undergraduate or graduate scholastic record. The letters have to be mailed or
emailed by the referee as follows:
The envelopes should be sealed and the seal should have the writer's signature across it.
- By postal mail to:
The Graduate Program Coordinator,
Department of Physics and
The University of Texas at Brownsville and Texas Southmost College,
80 Fort Brown,
Brownsville, TX 78520
- By email to: email@example.com with subject line of the email
containing the name of the student
- Statement of Purpose. Include a letter outlining your motivation why you want to
pursue a Masters in Physics. The statement can be provided during the online
- The following additional requirements apply for international students:
- TOEFL scores (www.ets.org/toefl) or IELTS scores (www.ielts.org). The scores
must be sent by the testing agency directly to the Univ ersity. For TOEFL
scores, the ETS code for the University of Texas at Brownsville is 6588.
- Foreign transcripts may be required to be translated and evaluated by a U.S.
based agency when necessary at additional cost to the stu dent. (Information on
these services is available at the Office of Graduate Studies).
- Financial Aid through Research and Teaching Assistanship is available for
- Applicants that do not meet the above criteria may qualify for conditional
admission as described in the Graduate Catalog.
- Contact address for the Department of Physics and Astronomy at UTB:
Graduate Program Coordinator Department of Physics and Astronomy The University of Texas
at Brownsville 80 Fort Brown Brownsville, TX 78520
The Master of Science program thesis option requires the successful comple-
tion of a minimum of 30 semester credit hours of Physics courses.
Required courses (6 sch ):
(repeated for a total of 6 sch)
Students must enroll in the Thesis course when recommended to do so by their
advisor. They must take this course until final approval has been granted by the
advisor. However, no more than six hours of this course will count toward the
M.S. degree. All candidates must comply with Office of Graduate Studies
guidelines regarding thesis application, submission and defense.
Elective courses ( 24 sch)
Twenty four semester credit hours of Physics courses are required to complete the
30 credit hours. These courses will form part of the students Program of
Study, with courses chosen to be appropriate for the background and research
interests of each student. In the typical case, a student will take PHYS 5310,
PHYS 5320, PHYS 5330 and PHYS 5340 as these are the traditional core courses for
more advanced study (e.g., Ph.D. degree) and research. Additional credit hours
may be taken from any of the elective physics courses or graduate courses
offered by other departments previously approved by the Department of Physics
and Astronomy Graduate Committee.
This option requires the successful completion of a minimum of 30 semester credit hours of Physics courses.
Comprehensive Exam: Non-thesis students must take a comprehensive written
or oral examination covering the student ’ s understanding of graduate
level Physics concepts. The comprehensive exam will be administered by a
departmental committee and the student shall choose between a written or
oral examination in consultation with this committee. The semester in which
the comprehensive exam is to be taken will appear on the program of study
of non-thesis students. It will not be scheduled prior to the student’s final
semester of coursework.
In the typical case, a student will take PHYS 5310, PHYS 5320,
PHYS 5330 and PHYS 5340 as these are the traditional core courses for more
advanced study (e.g., Ph.D. degree) and research. Additional credit hours may be
taken from any of the elective physics courses or graduate courses offered by
other departments previously approved by the Department of Physics and Astronomy
Every student admitted into the program will be required to set up a degree plan
in consultation with the graduate committee and approved by the department
chair. The degree plan will take into account the educational background of the
student and his/her future plans. It will consist of a timeline showing the
sequence of courses that the student needs to take in order to complete the
program successfully. Progress of the student through the program will be
measured against this baseline degree plan after the end of each semester. Any
changes needed to the degree plan, agreed upon by the student and the graduate
committee and approved by the department chair, will also come into effect at
the end of each semester.
Graduate Courses in Physics
Students wishing to enroll in the UTB/UTSA Cooperative PhD (Physics) Program may
be required to take: PHYS 5310, PHYS 5320, PHYS 5330 and PHYS 5340 as these are
required courses in the UTSA PhD degree program.
PHYS 5194 Advanced Statistical Methods for Modern Astronomy Laboratory
This graduate laboratory carries out the implementation in a Matlab environment
of the data analysis topics that are being covered in the course. The laboratory
has a well-designed curriculum to equip graduate students with the right skills
for their subsequent research in astronomical data analysis.
PHYS 5195 Graduate Seminar
This is a seminar course in which student presents research based on current
literature. It may be repeated three times for credit.
PHYS 5296 Introduction to Research
This is a two-credit course in which students practice elements of communication of research science. Prerequisite: Approval of graduate faculty advisor.
PHYS 5310 Classical Mechanics I
This graduate course will introduce students to Newtonian mechanics, Lagrangian and Hamiltonian dynamics, dynamics of rigid bodies, central force problem and orbital dynamics, symmetries and conservation laws, relativistic dynamics.
PHYS 5320 Electrodynamics I
This graduate course will cover electrostatics and magnetostatics, boundary value problems, Maxwell’s equations, plane waves, wave guides diffraction, multipole radiation.
PHYS 5330 Statistical Mechanics
This graduate course will introduce students to thermodynamics, equilibrium statistical mechanics, Boltzmann equation and the collision operator, moments of the Boltzmann equations, the Navier-Stokes equations, introduction to nonequilibrium concepts, ensembles, classical and quantum gases, statistical physics of solids.
PHYS 5340 Quantum Mechanics I
This graduate course will cover linear vector spaces and linear operators, postulates, Hilbert space formulation, the Schrödinger equation and one-dimensional problems, the hydrogen atom, symmetries, rotational invariance and angular momentum, spin, system with N-degrees of freedom.
PHYS 5360 Optics
This course is an introduction to the field of optics and its modern applications. The course will start with Huygens principle, the wave equation, and the superposition principle. Fraunhofer and Fresnel diffraction, coherence theory, interferometry, and Gaussian optics are among the topics that will also be covered. Co-requisite: PHYS 5320 or consent of instructor.
PHYS 5361 Applied Electromagnetics
This is an advanced graduate course in electromagnetic field theory and
electrodynamics, with particular emphasis on EM wave interaction with materials,
scattering and guided waves. The course will cover in great details the physics
underlying electromagnetic wave propagation and the engineering of devices such
as antennas, arrays, and periodic passive structures that take advantage of
these concepts. Prerequisites: PHYS 5320 and PHYS 5360.
PHYS 5375 Structure and Function of Biological Molecules
This course will provide in-depth assessment of structure of biological molecules, with emphasis on structure-function relationship. Physical principles underlying formation of secondary and tertiary structure of proteins, structural dynamics of DNA, and DNA-protein interactions will be reviewed. Prerequisites: Consent of the instructor. Mastery of differential equations and mathematical methods at an undergraduate level is expected.
PHYS 5387 Special Topics in Physics
This graduate course will introduce students to different topics. The topics will be announced. May be repeated for credit. Prerequisites: Instructor approval.
PHYS 5391 Quantum Mechanics in Chemistry
This graduate course will introduce the student to the use of quantum mechanics in chemistry. Topics to be covered include the basic models of quantum theory, perturbation theory, ab initio and density functional methods, semi empirical methods, group theory, and computational applications. Prerequisite: PHYS 5361.
PHYS 5392 Gravitational Wave Astronomy
This course provides a basic and broad description of astrophysics related to sources of gravitational radiation, gravitational wave detectors, numerical relativity, and data analysis.
PHYS 5393 Introduction to General Relativity and Gravitation
This graduate course introduces Einstein’s theory of relativity and other topics in the field of gravitation. Topics covered are the Principle of Equivalence, Introduction to Differential geometry and tensor analysis. Also studied are physics on curved manifolds, Einstein’s equations of General Relativity, exact solutions of Einstein’s equations, the Schwarzschild and Kerr solutions, Black Hole Physics and Cosmology, Gravitational radiation and its detection. Prerequisites: PHYS 3310, PHYS 3390, PHYS 3400, PHYS 4330.
PHYS 5394 Advanced Statistical Methods for Modern Astronomy
This course will introduce the student to: gravitational wave astronomy and the detectors, advanced statistical methods, computational methods, introduction to grid computing and the LSC grid. The course has a mandatory laboratory component which will train the students in advanced statistical data analysis and grid computing. Prerequisites: MATH 3447 Calculus III and PHYS 3490 Mathematics for scientists and engineers I, or consent of instructor.
PHYS 6320 Electrodynamics II
This course will introduce the student to relativistic formulation of Maxwell equations, radiation from moving charges, collisions of charged particles, radiation damping, introduction to plasmas, and magnetohydrodynamics. Prerequisite: PHYS 5320.
PHYS 6330 Quantum Mechanics II
This course will introduce the student to variational and WKB methods, timeindependent and time-dependent perturbation theory, scattering theory, path integration formulation, introduction to relativistic quantum mechanics and the Dirac equation. Prerequisite: PHYS 5340.
PHYS 6331 Solid State Physics
This graduate course will introduce the student to Lattice vibrations and thermal properties of solids, band theory of solids, transport properties of metals and semiconductors, optical properties, magnetic properties, magnetic relaxation, superconductivity, elementary excitations, interactions phonon-phonon, electron-electron, electron-phonon, theory of metals and semiconductors, transport theory, and optical properties. Prerequisite: PHYS 5340.
PHYS 6350 Mathematical Physics I
This graduate course will include linear algebra, ordinary and partial differential equations, special functions, eigenvalue problems, complex analysis, group theory.
PHYS 6351 Mathematical Physics II
This course will introduce the student to advanced topics in mathematical physics, topology, functional analysis, differentiable manifolds, Lie groups and algebras, and cohomology theory. Prerequisite: PHYS 6350.
PHYS 6352 Computational Physics
The course will cover introduction to numerical techniques for solving physics problems, theory of computation and applications to various branches of physics, sample problems might include chaotic motion and nonlinear dynamics, particle trajectories, Monte Carlo simulations, dynamical and statistical descriptions of many body problems, hyperbolic, parabolic, and elliptic differential equations.
PHYS 6362 Quantum Optics
This course introduces the student to non-linear optics and the new field of observing quantum effects in small groups of atoms, starting from a few and down to one. Topics include fiel quantization; emission and absorption of radiation by atoms; nonlinear optics and parametric conversion; non-classical light; optical tests of quantum mechanics; and experiments with trapped atoms. Prerequisites: PHYS 5360 and PHYS 5340 or consent of instructor.
PHYS 6363 Electromagnetic Matematerials
This course covers the electromagnetic characterization of matematerials that is engineered materials with characteristics which may not be found in nature, with particular emphasis on technological applications. The course provides a deep insight into the fundamental physics needed to fully grasp the technology of antennas, arrays, and frequency selective surfaces using non-conventional materials. Prerequisite: PHYS 5361 or consent of instructor
PHYS 6364 Nanophotonics: materials and devices
This course will cover general concepts of nanophotonics which is a new field of physics focused on studies of interaction of light with matter on the nanometer scale. Topics covered will include near-field optics, photonic crystals, negative index materials, nanocavities, integrated photonic circuits, and their fabrication techniques. Prerequisites: PHYS 5320 and PHYS 5360 or consent of instructor.
PHYS 6371 Thermodynamics and Kinetics of Biological Systems
This course provides students with fundamentals of statistical thermodynamics, electrostatics and electrochemistry, enzyme kinetics, and molecular driving forces. Prerequisites: Consent of the instructor.
PHYS 6373 Statistical Physics of Molecular Cell Biology
This course introduces students to the basic physical laws governing the life of cells and its material and explains the latest research regarding physical aspects of molecular cell biology, and discusses physical methods used in today’s laboratories. Prerequisites: Consent of instructor.
PHYS 6381 Introduction to Astrophysics
This graduate course will introduce students to a range of basic topics in astrophysics: stars, stellar evolution, neutron stars, black holes, galactic dynamics, galaxies, large scale structure in the Universe and cosmology. Prerequisites: PHYS 5320 and PHYS 5310.
PHYS 6386 Research Problems in Physics
This graduate course is required for the 30-hour non-thesis option. To pass the course students have to present a typewritten report. May be repeated for credit; maximum credit allowed is six hours. May not be counted as thesis research but may be taken one time as a preparatory investigation course prior to the beginning of thesis research.
PHYS 6396 Graduate Research in Physics
This graduate course is a research in physics course in preparation for thesis work (Research I). Prerequisite: graduate advisor approval.
PHYS 6398 Thesis
This graduate course initiates students in their thesis work. Prerequisites:
graduate advisor approval.