Main Departmental Office
North Texas Research Park, Room E132
P.O. Box 305310
Denton, TX 76203-5310
Fax: (940) 565-4824
Web site: www.mtsc.unt.edu
Professors Brostow, Kaufman. Associate Professors Banerjee, D’Souza, El Bouanani, Reidy. Assistant Professors Gorman, Scharf, Shepherd. Visiting Professor Needleman.
The Department of Materials Science and Engineering addresses the education and technological challenges of creating, applying and characterizing new materials for the 21st century. The Department of Materials Science and Engineering is committed to training students at the undergraduate and graduate levels in all aspects of modern materials including metals, ceramics, polymers, electronic and optical materials and materials characterization. Students have opportunities for hands-on instruction and research with modern equipment and facilities. The department has strong collaborative programs with industries in the Dallas–Fort Worth region and with universities both locally and throughout the world.
The department offers bachelor of science, master of science and doctoral degrees, all with a major in materials science and engineering. The undergraduate program was approved in July 2006 and started admitting students immediately. Presently, the department has nine tenured or tenure track faculty who divide their time between teaching and research in the different areas mentioned above. Research support comes from a variety of federal, state and industrial entities. The department has one of the most advanced analytical characterization facilities in the country and both undergraduate and graduate students receive training on state-of-the-art equipment. Finally, the department has strong connections to local industries and is setting up relationships for cooperative education experiences and internships so that students can receive practical training in addition to the classroom and laboratory instruction. Students who graduate with a bachelor of science degree with a major in materials science and engineering can expect a very healthy job market and relatively high starting salaries in a variety of industries. In fact, materials science and engineering graduates are heavily sought after by industries of all types, including automotive, chemical, aerospace, microelectronics, magnetic storage, transportation, sports, defense, forensics, and manufacturing. A BS degree with a major in materials science and engineering also prepares students for continuing their education with a master’s or a PhD degree either in materials science and engineering or in a related field.
The vision of the Department of Materials Science and Engineering at the University of North Texas is to: have a world-class materials science and engineering research program with local, national and international scientific and technological impact; provide an outstanding educational experience for a diverse student population; and provide a collegial environment for students, staff and faculty.
The mission of the Department of Materials Science and Engineering is to provide a high quality engineering education to our diverse student population by maintaining a balance between the theoretical and applied aspects of materials science and engineering through course work, laboratories and independent research topics. The department provides national and international leadership in research and scholarship, and strives to build mutually beneficial partnerships with both internal and external collaborators, with alumni and with the professional and business communities. Finally, the department facilitates a collegial atmosphere that is conducive to the intellectual and scholarly pursuits of its faculty and students.
The Laboratory of Polymers and Composites works on reliability and prediction of service performance, polymer liquid crystals and their blends, fiber reinforced composites and polymer solutions. Mechanical, thermophysical and rheological properties are investigated using computer simulations, statistical mechanics and a variety of experimental techniques (DMTA, TMA, TSD, DSC, TGA, PV-T relations, computerized tension, compressions, blending and impact testing).
The Electron and Ion Microscopy Laboratory currently houses an FEI Tecnai F20ST TEM, an FEI Analytical Dual Beam FIB, an FEI Quanta Environmental SEM, an Imago Local Electrode Atom Probe, a Phillips EM420 TEM, a JEOL 5800 SEM and several optical microscopes for characterization of virtually any material. This equipment is being used to characterize a range of materials including semiconductors, nanocomposites, crystalline and amorphous alloys, advanced ceramics, polymers and polymer composites, and biomaterials.
The Material Mechanics Laboratory is engaged in investigations of interrelationships between morphology and mechanical properties through the influences of time and temperature. A Mechanical Testing System (MTS810) equipped with an environmental chamber, video and thermal wave imaging provides stress pattern-temperature relationships around propagating cracks. Dynamic Mechanical Thermal Analysis provides viscoelastic and rheological property evaluation. The laboratory is also engaged in thermally stimulated depolarization experimental techniques of polymer blends.
The Materials Synthesis and Processing Laboratory has research interests focused on the development of ferroelectrics, aerogels, and other novel ceramics for energy, sensor and high temperature applications. Equipment includes a critical point dryer, a BET surface area analyzer, electrical conductivity apparatus, high temperature furnaces and a controlled atmosphere glove box.
The Laboratory for Electronic Materials and Devices is working on basic and applied research for novel materials for advanced electronic devices of all kinds. The laboratory provides semiconductor-related materials growth and characterization capabilities that are available in only a few academic laboratories in the world. The laboratory is centered around a cluster multichamber MBE Group IV Metallization and Dielectric deposition system, coupled to a comprehensive surface science system as well as a 3 MV ion beam accelerator for in-situ materials processing and characterization. Research areas include growth, processing and characterization of novel electronic thin film materials such as dielectrics, advanced electrode materials with work function tuning, metallization, diffusion barriers, hydrogen and impurity defects in electronic nanostructures, stability, and interfacial diffusion/reaction in multilayered thin film nanostructures.
The Energy Materials Laboratory works on research that addresses the processing, characterization, and overall device development for energy conversion technologies. Low-temperature processing of ceramic thin films is achieved through the development of oxide polymeric precursors and colloidal suspensions. Deposition techniques such as laser assisted maskless aerosol deposition and spin coating are also studied. Applications of these materials processing techniques include transparent conducting oxides for flexible photovoltaics and displays, low operation temperature thin film solid oxide fuel cells, direct conversion of biofuels, and UV-Vis emitters and phosphors for solid state lighting. Extensive overlap exists between the Energy Materials Laboratory and the Electron Microscopy Laboratory. Additional characterization is available in this laboratory through electrochemical impedance spectroscopy, UV-Vis-NIR spectrophotometry, and X-ray diffraction.
The department offers undergraduate and graduate programs in the following areas:
The Bachelor of Science degree with a major in materials science and engineering is designed to provide students with the fundamental principles of how materials are made, how they behave during application, how their structure and properties are measured and quantified, and how to improve the performance of these materials. This information is then used in “materials-specific” courses and hands-on laboratories where students then learn to apply these principles to the different materials classes, namely, metals, ceramics, polymers, electronic materials and biomaterials. Students also learn about nanotechnology and how it is impacting the materials science and engineering discipline. During their last year, students are required to do a senior project with one of the faculty members who specialize in their primary area of interest. Students work either individually or in small groups on projects that provide them with research experiences that help them determine whether they feel better suited to finish their education and go to industry or continue on to graduate school. The course work instills in students ethical and environmental issues and standards expected by industry and society.
The bachelor of science degree with a major in materials science and engineering is a new program designed to meet ABET criteria. Accreditation for this degree will be sought as soon as the program graduates its first class of students.
1. Hours Required and General/College Requirements: A minimum of 131 semester hours, of which 54 must be advanced, and fulfillment of degree requirements for the Bachelor of Science degree as specified in the “General University Requirements” in the Academics section of this catalog and the College of Engineering requirements.
2. Major Requirements: A minimum of 54 semester hours, including MTSE 3010, 3020, 3030, 3040, 3050, 3060, 3070, 3080, 3090, 3100, 4010, 4020, 4030, 4040, 4050, 4060, 4070, 4090 and 4100; one elective MTSE course.
3. Other Required Courses:
a. MATH 1710, 1720 and 3310.
b. PHYS 1710/1730, 2220/2240 and 3010/3030.
c. CHEM 1410/1430 and 1420/1440.
d. ENGR 2303 and 2332.
e. MFET 3450.
4. Minor: Optional.
5. Electives: See four-year plan.
6. Other Requirements: A grade point average of at least 2.5 is required for all materials science and engineering courses.
Following is one suggested four-year degree plan. Students are encouraged to see their adviser each semester for help with program decisions and enrollment. Students are responsible for meeting all course prerequisites.
|CHEM 1410, General Chemistry for Science Majors||3|
|CHEM 1430, Laboratory Sequence for General Chemistry||1|
|ENGL 1310, College Writing I, or ENGL 1313, Computer Assisted College Writing I*||3|
|MATH 1710, Calculus I||4|
|PSCI 1040, American Government I*||3|
|Social and Behavioral Sciences*||3|
|ENGL 2700, Technical Writing**||3|
|ENGR 2060, Professional Presentations||3|
|CHEM 1420, General Chemistry for Science Majors||3|
|CHEM 1440, Laboratory Sequence for General Chemistry||1|
|MATH 1720, Calculus II||3|
|PHYS 1710, Mechanics||3|
|PHYS 1730, Laboratory in Mechanics||1|
|ENGR 2303, Statics and Dynamics||4|
|HIST 2610, United States History to 1865*||3|
|MATH 3310, Differential Equations for Engineering Majors||3|
|PHYS 2220, Electricity and Magnetism||3|
|PHYS 2240, Laboratory in Wave Motion, Electricity, Magnetism and Optics||1|
|Cross-Cultural, Diversity and Global Studies*||3|
|ENGR 2332, Mechanics of Materials||3|
HIST 2620, United States History Since 1865*
|MFET 3450, Engineering Materials||4|
|PHYS 3010, Modern Physics||3|
|PHYS 3030, Laboratory in Modern Physics||1|
|MTSE 3010, Bonding and Structure||3|
|MTSE 3020, Microstructure and Characterization of Materials||3|
|MTSE 3030, Thermodynamics and Phase Diagrams||3|
|MTSE 3040, Transport Phenomena in Materials||3|
|MTSE 3090, Materials Science and Engineering Laboratory I||1|
|Visual and Performing Arts*||3|
|MTSE 3050, Mechanical Properties of Materials||3|
|MTSE 3060, Phase Transformations in Materials||3|
|MTSE, 3070, Electrical, Optical and Magnetic Properties of Materials||3|
|MTSE 3080, Materials Processing||3|
|MTSE 3100, Materials Science and Engineering Laboratory II||2|
|PSCI 1050, American Government II*||3|
|MTSE 4010, Physical Metallurgy Principles||3|
|MTSE 4030, Ceramic Science and Engineering||3|
|MTSE 4050, Polymer Science and Engineering||3|
|MTSE 4070, Electronic Materials||3|
|MTSE 4090, Senior Research Project I||2|
|EENG 4020, Advanced Topics in Electrical Engineering II||3|
|MTSE 4040, Computational Materials Science||3|
|MTSE 4060, Materials Selection and Performance||3|
|MTSE 4100, Senior Research Project II||2|
|MTSE Technical Elective (4000 level)||3|
*See the University Core Curriculum section of this catalog for approved list of course options.
** See College of Engineering degree requirements section of this catalog for approved list of course options.
Actual degree plans may vary depending on availability of courses in a given semester.
Some courses may require prerequisites not listed.
The minor in materials science and engineering requires a total of 19 semester credit hours: 15 hours of materials science and engineering courses, plus MFET 3450, Engineering Materials (4 hours). At least 6 of the 15 hours in materials science and engineering should be from any two of the four core courses: MTSE 3010, MTSE 3030, MTSE 3050 and MTSE 3070. The remaining 9 hours can be from any other 3000- or 4000-level materials science engineering courses.
Note: The prerequisite of MFET 2100 for MFET 3450 is waived for students registering for a minor in materials science and engineering; however, the other prerequisites for MFET 3450 (CHEM 1410/1430 and MATH 1710) must be completed by students registering for the minor in materials sciences and engineering.
All Courses of Instruction are located in one section at the back of this catalog.
Date of initial release: July 1, 2007 — Copyright © 2007 University of North Texas
Page updated: September 5, 2007 — Comments or corrections: firstname.lastname@example.org
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