M.S., M.Engr., Ph.D.
Thesis (M.S.), Thesis Substitute (M.Engr.) and Non-Thesis (M.Engr.)
Ronald L. Elsenbaumer
325 Woolf Hall, 817-272-2398
Pranesh B. Aswath
325D Woolf Hall, 817-272-2008
Aswath, Chan, Elsenbaumer, Goolsby, Johnson
Graduate faculty from participating departments and programs in the College of Engineering and the College of Science are involved in teaching and supervising materials science and engineering graduate students' research. Specific faculty contacts within these areas include:
Aerospace Engineering: Professor Joshi, 215 Woolf Hall, 817-272-3746
Biomedical Engineering: Assistant Professor Nelson, 225 Engineering Lab,
Chemistry: Professor Elsenbaumer, 219 Science, 817-272-3171
Civil Engineering: Professor Yuan, 408 Nedderman Hall, 817-272-2550
Electrical Engineering: Professor Carter, 532 Nedderman Hall, 817-272-3466
Mechanical Engineering: Professor Chan, 325G Woolf Hall, 817-272-5638
Physics: Professor Weiss, 107D Science, 817-272-2459
Participating faculty of the colleges of Engineering and Science
Aerospace Engineering: Joshi
Biomedical Engineering: Eberhart, Nelson
Chemistry: Dias, Kinsel, Marynick, McDowell, Pomerantz, Rajeshwar, Timmons
Civil Engineering: Yuan
Electrical Engineering: Carter, Davis, Kirk, Maldonado
Mechanical Engineering: Chan, Haji-Sheikh, Nomura, Wang
Physics: Black, Fry, Koymen, Ray, Sharma, Weiss, West
The graduate program in materials science and engineering is designed to provide students with a fundamental understanding of phenomena occurring in materials and their associated chemical, electrical, mechanical, and physical properties. The master's program prepares students for professional careers in materials science and engineering or for additional studies at the doctoral level.
Candidates for a master's or doctoral degree may elect programs emphasizing metals, polymers, ceramics, composite materials, or electronic materials, as well as a number of other areas. Although the program is administered through the College of Engineering, it is broadly interdisciplinary, actively involving faculty in both the College of Science and the College of Engineering. In addition to materials science and engineering courses, applicable courses are in the disciplines of aerospace engineering, biomedical engineering, chemistry, civil engineering, computer science engineering, electrical engineering, mechanical engineering, and physics.
Applicants for the master's degree who hold a baccalaureate in engineering or science must meet the general requirements of the Graduate School as stated in the section of this catalog entitled "Admission Requirements and Procedures." Applicants not meeting all criteria may be admitted on a provisional or probationary basis.
For applicants with no prior training in engineering or with insufficient undergraduate materials coursework, the same minimum criteria will apply. Additionally, their records will be reviewed in relation to their materials backgrounds, and probationary status with specific remedial work required may be a basis for acceptance of such applicants.
The acceptance of applicants who hold a master's degree in engineering will be based on the above-mentioned minimum criteria and results of graduate work, including the master's thesis.
Applicants for the doctoral degree must have either a baccalaureate or master's degree in engineering or science and meet all requirements stated above in both graduate and undergraduate work. Students without a master's degree will enter the program as master's candidates and must complete a minimum of 30 graduate semester hours (at least 24 hours of which must be coursework) with distinction prior to advancement to doctoral candidacy. Doctoral candidates shall also demonstrate through previous academic preparation the potential to carry out independent research in materials science and engineering.
The Materials Science and Engineering Program proposes the following guidelines for unconditional admission to our graduate programs. In evaluating candidates, the preparedness of the student as evidenced by quality and quantity of coursework and the student's previous research experience are emphasized. Recommendations from the MSE faculty, based on firsthand knowledge of the applicant or a faculty member at the applicant's institution, are also very important.
Use any one of the following options. All options require a GPA of 3.0 in the last 60 hours of undergraduate work as calculated by the Graduate School.
A satisfactory completion of a Bachelor's degree or equivalent, official transcripts, and GRE scores, and three letters of recommendation. An applicant whose native language is not English must submit a TOEFL score of at least 550. The TSE-A (score of 45 or higher) can be substituted for the TOEFL.
A satisfactory completion of a Bachelor's degree or equivalent, official transcripts, and a letter of recommendation from a faculty member at the applicant's undergraduate institution, plus a recommendation for a UTA faculty member who participates in the Materials Science and Engineering Program. An applicant whose native language is not English must submit a TOEFL score of at least 550. A TSE-A score of 45 or higher can be substituted for the TOEFL. Those who have completed their undergraduate education in English may be eligible for a TOEFL waiver based on the recommendation letters.
A satisfactory completion of a Bachelor's degree or equivalent, official transcripts, and a letter of recommendation from a faculty member at the undergraduate institution, plus a recommendation from a UTA faculty member who participates in the Materials Science and Engineering Program based on a face-to-face interview and/or direct e-mail contact.
In rare cases, probationary admission may be granted as the result of a substandard performance on the admission criteria. In this case, the Graduate Advisor will set additional conditions for admission including, but not limited to, additional undergraduate coursework and/or achieving a B or better in the first 12 hours of graduate coursework.
An applicant unable to supply all required documentation prior to the admission deadline but who otherwise appears to meet admission requirements may be granted provisional admission.
A deferred decision may be granted when a file is incomplete or when a denied decision is not appropriate.
Denial of Admission
A candidate may be denied admission if they have less than satisfactory performance on a majority (3 or more) of the admission criteria described below:
Students that are unconditionally admitted will be eligible for available scholarship and/or fellowship support. Award of scholarships or fellowships will be based on the following criteria:
The Materials Science and Engineering Graduate Program, in fulfillment of its responsibility to graduate highly qualified professional engineers and scientists, has established certain policies and procedures. In addition to the requirements of the Graduate School listed elsewhere in this catalog, to continue in the program each materials science and engineering graduate student must:
At such time as questions are raised by materials science and engineering graduate faculty regarding either of the above, the student will be notified and will be given the opportunity to respond to the Committee on Graduate Studies for Materials Science and Engineering. The Committee on Graduate Studies will review the student's performance and make a recommendation concerning the student's eligibility to continue in the program. Appeal of a decision on continuation may be made through normal procedures outlined in the section of this catalog entitled "Grievances Other Than Grades."
Master of Science in Materials Science and Engineering: The Master of Science degree is a research-oriented degree in which completion of a thesis is mandatory. The program consists of a minimum of 24 credit hours of coursework and an acceptable thesis (minimum of six credit hours).
Master of Engineering in Materials Science and Engineering: The Master of Engineering degree is an engineering practice-oriented program requiring a minimum of 36 credit hours. A maximum of six hours may be a special project. A final program examination is required of all master's degree candidates. Non-thesis degree candidates will fulfill the program examination requirement upon the successful completion of MSE 5192, Master's Comprehensive Examination. Candidates must enroll in MSE 5192 in the semester they intend to graduate.
The Ph.D. degree program involves an interdisciplinary and multidisciplinary approach which requires students to complete a set of Materials Science and Engineering core courses augmented by elective offerings in aerospace engineering, biomedical engineering, chemistry, civil engineering, electrical engineering, materials science, mechanical engineering and physics. The degree is a research degree which requires the candidate successfully to carry out independent research in an area acceptable to the Committee on Graduate Studies for Materials Science and Engineering. A student's research is directed by a faculty member from any of the departments or programs participating in the Materials Science and Engineering Program.
The Ph.D. degree program requires successful completion of the following curriculum components:
1. A minimum of 24 semester hours of graduate coursework is expected for students entering with an appropriate master's degree or, for highly qualified students, a minimum of 42 semester hours of graduate coursework is expected for student's entering with a bachelor's degree, as approved by the Committee on Graduate Studies for Materials Science and Engineering. Additional coursework may be required by the student's doctoral dissertation committee.
2. Four core courses or their equivalent are required for all
MSE 5304. Analysis of Materials MSE 5305. Physics and Thermodynamics of Materials
MSE 5312. Mechanical Behavior of Materials MSE 5321. Phase Transformations of Materials
3. One of these two courses are required for all
MSE 5345. Ceramic Materials
MSE 5347. Polymer Materials Science
4. Three of the following supplemental elective courses must
be taken by all doctoral students, as approved by the
Committee on Graduate Studies for Materials Science and Engineering.
MSE 5310. Dislocation Theory
MSE 5314. Fracture Mechanics
MSE 5315. Fatigue of Engineering Materials
MSE 5335. Integrated Circuit Materials and Processing
MSE 5336. Electrical Properties of Materials
MSE 5337. Magnetic and Optical Properties of Materials
MSE 5345. Ceramic Materials
MSE 5346. Contemporary Polymer Chemistry
MSE 5347. Polymer Materials Science
MSE 5348. Fundamentals of Composites
MSE 5349. Advanced Composites
BME 5332D. Orthopedic Biomaterials
BME 5335. Biological Materials, Mechanics and Processes
BME 5361D. Biomaterials and Blood Compatibility
CHEM 5309. Organic Chemistry I
CHEM 5350. Advanced Polymer Chemistry
CHEM 5461. Analytical Instrumentation
CHEM 6305. Special Topics in Applied Chemistry
EE 5340. Semiconductor Device Theory I
EE 5343. Integrated Circuit Techniques
EE 5349. Topics in Integrated Circuit Technology
EE 6342. Advanced Quantum Devices
ME 5312. Continuum Mechanics
ME 5314. Fracture Mechanics in Structural Design
ME 5339. Structural Aspects of Design
PHYS 5316. Solid State II
PHYS 6302. Methods of Applied Physics II Computers in Physics
5. Elective courses will be taken by all doctoral students which will allow specialization within a particular academic discipline. Graduate courses in chemistry, physics and engineering will be selected for this purpose in consultation with the student's research advisor, subject to approval by the Committee on Graduate Studies for Materials Science and Engineering.
After completion of the first year's coursework (i.e., core courses), students must satisfactorily complete diagnostic examinations which may be written or oral or written and oral with a supplemental interview with faculty members, as determined by the Committee on Graduate Studies in Materials Science and Engineering.
Upon completion of all or nearly all of the coursework requirements and after having demonstrated research ability through partial completion of dissertation research, a student must satisfactorily complete a comprehensive examination.
The dissertation research will be formulated in conjunction with the student's faculty research advisor who may be associated with any of the following academic disciplines participating in the Materials Science and Engineering Program: aerospace engineering, biomedical engineering, chemistry, civil engineering, electrical engineering, materials science, mechanical engineering, and physics. The dissertation research represents the culmination of the student's academic efforts and is expected to demonstrate original and independent research activity and be a significant contribution to knowledge in the field.
The grade of R (research in progress) is a permanent grade; it cannot be changed by completing course requirements in a later semester. To receive credit for an R-graded course, the student must continue to enroll in the course until a passing grade is received.
An incomplete grade (the grade of X) cannot be given in a course that is graded R, nor can the grade of R be given in a course that is graded X. To receive credit for a course in which the student earned an X, the student must complete the course requirements. A grade of X cannot be changed by enrolling again in the course in which an X was earned. At the discretion of the instructor, a final grade can be assigned through a change of grade form.
Three-hour thesis courses and three- and six-hour dissertation courses are graded R/F/W only (except social work thesis courses). The grade of P (required for degree completion for students enrolled in thesis or dissertation programs) can be earned only in six- or nine-hour thesis courses and nine-hour dissertation courses. In the course listings below, R-graded courses are designated either "Graded P/F/R" or "Graded R." Occasionally, the valid grades for a course change. Students should consult the appropriate Graduate Advisor or instructor for valid grade information for particular courses. (See also the sections titled "R" Grade, Credit for Research, Internship, Thesis or Dissertation Courses and Incomplete Grade in this catalog.)
Course fee information is published in the online Student Schedule of Classes at www.uta.edu/schedule. Please refer to this Web site for a detailed listing of specific course fees.
5300. INTRODUCTION TO MATERIALS SCIENCE AND ENGINEERING (3-0). Physical, mechanical, electrical and chemical properties of metals, semiconductors, ceramics, polymers and composites, with an emphasis on understanding fundamental issues. Relationships between the processing, micro and macro structure of materials with their properties, such as strength ductility, toughness, fatigue and fracture and creep properties with special emphasis on mechanical properties of metals, polymers, ceramics and composites. Prerequisite: permission of instructor.
5304. ANALYSIS OF MATERIALS (2-3). Theoretical understandings and practical applications of various characterization techniques to materials analysis, ranging from x-rays and electron diffraction, x-ray spectroscopy, and surface topography, are discussed. Practice of these techniques in lab class typically includes SEM spectroscopy, powder diffraction, Laue diffraction, and the double crystal x-ray diffraction. Prerequisite: permission of instructor.
5305. PHYSICS AND THERMODYNAMICS OF MATERIALS (3-0). Applications of solid-state physics and thermodynamics for fundamental understanding of materials. The solid state physics discusses the mechanisms behind crystal bonding, lattice structure and its property, and band structure of electrons, while thermodynamics focuses on their changes with thermal, chemical and mechanical processes using the concept of thermochemistry. Prerequisites: permission of instructor.
5310. DISLOCATION THEORY (3-0). Theory of dislocations and their reactions and interactions in crystalline materials developed and extended into a basic understanding of mechanical properties of crystalline materials. Prerequisite: permission of instructor.
5312. MECHANICAL BEHAVIOR OF MATERIALS (3-0). Concepts of stress and strain, theory of plasticity. Elementary dislocation theory. Deformation of single crystals. Strengthening mechanisms like solid solution strengthening, precipitation hardening, etc. Elementary concepts in fracture mechanics. Microscopic aspects of fracture, fatigue, and creep of materials. Prerequisite: MAE 3321, MSE 5300 or permission of instructor.
5314. FRACTURE MECHANICS (3-0). Theory and applications of linear elastic fracture mechanics. Topics include stress analysis of cracks, crack-tip plasticity, fatigue and stress corrosion. Applicability to materials selection, failure analysis and structural reliability reviewed. Prerequisite: permission of instructor.
5315. FATIGUE OF ENGINEERING MATERIALS (3-0). Cyclic deformation, fatigue crack initiation and growth in ductile solids. Application of fracture mechanics to fatigue. Mechanisms of crack closure. Variable and multiaxial fatigue and corrosion fatigue. Fatigue of brittle solids. Prerequisite: permission of instructor.
5321. PHASE TRANSFORMATIONS OF MATERIALS (3-0). The theory of homogeneous and heterogeneous transformations, nucleation and growth, martensitic transformations, heat treatment and control of microstructure. Prerequisite: MSE 5300, MSE 5305, or permission of instructor.
5330. CORROSION (3-0). Quantitative application of electrochemical principles to corrosion reactions. Effects of metallurgical factors and environmental conditions on oxidation, erosion, and cracking discussed along with materials selection. Prerequisite: permission of instructor.
5335. INTEGRATED CIRCUIT MATERIALS AND PROCESSING (3-0). Fundamental properties of conductors, semiconductors, insulators, and polymers. Basic device operating principles for the pn junction, MOSFET, and Schottky diode. Materials processing for oxidation, annealing, thin film deposition, wet chemical etching, reactive ion etching, ion implantation, planarization, and photolithography. Prerequisite: permission of instructor.
5336. ELECTRICAL PROPERTIES OF MATERIALS (3-0). Advanced discussion of electronic structure, transport mechanisms in metals, semiconductors and superconductors, with applications to materials used in various electronic devices. Prerequisite: MSE 5305 or permission of instructor.
5337. MAGNETIC AND OPTICAL PROPERTIES OF MATERIALS (3-0). Classical and quantum mechanical understandings of magnetic and optical properties and phase transition phenomena. Specific applications of these properties to various devices are discussed. Prerequisite: MSE 5305 or permission of instructor.
5338. RELIABILITY AND FAILURE OF ELECTRONIC PACKAGING (3-0). Review of materials for substrate, interconnect, encapsulation and passivation. Types of packaging like insertion, SMT, FCOB, etc. Manufacturing processes and reliability. Failure mechanisms like metallization and interconnect degradation, thermomechanical failure, warpage, fatigue failure, delamination and brittle fracture. Experimental validation methods, including SEM, X-ray, etc. Prerequisites: permission of instructor.
5341. TRANSMISSION ELECTRON MICROSCOPY IN MATERIALS SCIENCE (3-0). Crystallography, stereographic projections, and reciprocal lattice. Specimen preparation in transmission electron microscopy. Dynamical and kinematical theories of electron diffraction. Interpretation of diffraction patterns and transmission electron micrographs. Use of the transmission electron microscope. Prerequisites: MSE 5304, MSE 5305 or permission of instructor.
5345. CERAMIC MATERIALS (3-0). Crystal structure of ceramic materials. Phase equilibria in ceramic materials. The processing of ceramics and ceramic matrix composites. Strengthening mechanisms and mechanical properties of ceramics and ceramic matrix composites including flexure, tensile, fracture toughness, fatigue, and creep. Prerequisites: MSE 5300 or permission of instructor.
5346. CONTEMPORARY POLYMER CHEMISTRY (3-0). Polymer synthesis and reactions. Principles of polymerization including thermodynamics and kinetic considerations. Physical characterizations including determinations of absolute and relative molecular weights, morphology, and glass transitions. Relationships between macromolecular structure, properties, and uses of polymeric materials. Also offered as CHEM 5350. Prerequisites: CHEM 2321 and CHEM 2322 or permission of instructor.
5347. POLYMER MATERIALS SCIENCE (3-0). Intermolecular forces of attraction in high polymers, polymer synthesis, morphology and order in crystalline polymers, mechanics of amorphous polymers, time-dependent mechanical behavior, transitional phenomena, mechanical behavior of semicrystalline polymers. Prerequisite: MSE 5300 or permission of instructor.
5348. FUNDAMENTALS OF COMPOSITES (3-0). Fundamental mechanics concepts of fiber-reinforced composites; relationships between the properties of the constituents and those of the unit composite ply; lamina and laminate anisotropic behavior; structural characteristics of A, B, and D matrices; lamination theory; strength criteria; hygrothermal analysis; interlaminar stress analysis. Also offered as ME 5348 and AE 5315. Prerequisite: permission of instructor.
5349. ADVANCED COMPOSITES (3-0). Review of current state-of-the-art applications of composites; composite structural analysis; structural properties; damage characterization and failure mechanism; stiffness loss due to damage; notched sensitivity; delamination; impact; fatigue characteristics; composite materials testing; materials allowables; characteristics of composite joints. Also offered as AE 5325 and ME 5349. Prerequisites: ME 5348 or MSE 5348 or AE 5315 or permission of instructor.
5350. EXPERIMENTAL CHARACTERIZATION OF COMPOSITES (2-3). Laminate processing, NDI, and physical characterization procedures; thermal analysis methods for composites; composite materials tensile, compressive, shear, flexure, thermoelastic, and interlaminar fracture characterizations. Prerequisite: MSE 5348, ME 5348, or AE 5315 or concurrent enrollment or permission of instructor.
5141. TRANSMISSION ELECTRON MICROSCOPY LAB (0-1). Specimen preparation. Operation of the transmission electron microscope. Beam alignment and rotation calibration. Bright field and dark field imaging. Weak beam imaging. Examination of defects. Prerequisites: MSE 5300, MSE 5304, and permission of instructor. Co-requisite: MSE 5341.
5190, 5290, 5390. SPECIAL TOPICS IN MATERIALS SCIENCE AND ENGINEERING. May be repeated for credit when topic changes. Prerequisite: Consent of instructor.
5191, 5291, 5391. ADVANCED STUDIES IN MATERIALS SCIENCE AND ENGINEERING. Topics selected from various areas of materials science and engineering. Work performed as a thesis substitute normally will be accomplished under the course number 5391, with prior approval of the Committee on Graduate Studies. Graded R.
5192. MASTER'S COMPREHENSIVE EXAMINATION. Directed study, consultation, and comprehensive examination over coursework leading to the Master of Engineering degree in Materials Science and Engineering. Required of all Master of Engineering students in the semester they plan to graduate. Graded P/F/R.
5193. SEMINAR IN MATERIALS SCIENCE AND ENGINEERING (1-0). Selected topics in materials science and engineering presented by faculty, students, and invited lecturers.
5398, 5698, 5998. THESIS. 5398 graded R/F only; 5698 and 5998 graded P/F/R. Prerequisite: approval of Graduate Advisor.
6196, 6396, 6696, 6996. MSE INTERNSHIP. For students participating in internship programs. May be repeated for credit. Prerequisite: approval of Graduate Advisor. Graded P/F/R.
6197, 6397. ADVANCED STUDIES IN MATERIALS SCIENCE AND ENGINEERING. May be repeated for credit. Prerequisite: approval of Graduate Advisor. Graded R.
6198-6998. RESEARCH IN MATERIALS SCIENCE AND ENGINEERING. Individually approved research projects in materials science and engineering. May be repeated for credit. Graded P/F/R.
6399, 6699, 6999. DISSERTATION. 6399 and 6699 graded R/F only; 6999 graded P/F/R.