Chemical and Nuclear Engineering

Timothy L. Ward, Chairperson
Department of Chemical and Nuclear Engineering
Farris Engineering Center 209
MSC01 1120
1 University of New Mexico
Albuquerque, NM 87131-0001
(505) 277-5431

Professors
Plamen Atanassov, Ph.D., Bulgarian Academy of Science
C. Jeffrey Brinker, Ph.D., Rutgers University
Joseph L. Cecchi, Ph.D., Harvard University
Abhaya K. Datye, Ph.D., University of Michigan
Cassiano de Oliveira, Ph.D., University of London
Mohamed S. El-Genk, Ph.D., University of New Mexico
Julia E. Fulghum, Ph.D., University of North Carolina
Philip Heintz, Ph.D., University of Washington
Anil K. Prinja, Ph.D., University of London
Andrew P. Shreve, Ph.D., Cornell University
Timothy L. Ward, Ph.D., University of Washington*

Associate Professors
Heather Canavan, Ph.D., George Washington University
Gary W. Cooper, Ph.D., University of Illinois
Steven W. Graves, Ph.D., Pennsylvania State University
Sang. M. Han, Ph.D., University of California-Santa Barbara
Dimiter Petsev, Ph.D., University of Sofia

Assistant Professors
Edward D. Blandford, Ph.D., University of California - Berkeley
Eva Y. Chi, Ph.D., University of Colorado - Boulder
Elizabeth L. Dirk, Ph.D., Rice University
Jeremy S. Edwards, Ph.D., University of California, San Diego
Adam Hecht, Ph.D., Yale University

Professor Emeriti
Harold M. Anderson, Ph.D., Wayne State University
David Kauffman, Ph.D., University of Colorado*
Richard W. Mead, Ph.D., University of Arizona*
Norman F. Roderick, Ph.D., University of Michigan

Lecturer III
Robert D. Busch, Ph.D., University of New Mexico*

The University of New Mexico National Laboratory Professors
John G. Curro, Ph.D., California Institute of Technology
Ronald E. Loehman, Ph.D., Purdue University
Peter Randall Schunk, Ph.D., University of Minnesota

Research Professors
Edward Arthur, Ph.D., University of Virginia
James P. Freyer, Ph.D., University of Rochester
Gabriel P. Lopez, Ph.D., University of Washington
Scott S. Sibbett, Ph.D., Oregon Health & Science University
David Whitten, Ph.D., Johns Hopkins University

Research Associate Professor
Kateryna Artyushkova, Ph.D., Kent State University
Boris Kiefer, Ph.D., University of Michigan
Yixiang Xie, Ph.D., Missouri University of Science and Technology

Research Assistant Professors
Eric Carnes, Ph.D., University of New Mexico
Darren Dunphy, Ph.D., University of Arizona
Hongyou Fan, Ph.D., University of New Mexico
Barr Halevi, Ph.D., University of Pennsylvania
Hien Pham, Ph.D., University of New Mexico
Jean-Michel Tournier, Ph.D., University of New Mexico

Affiliated Faculty
Christopher A Apblett, Ph.D., Rensselaer Polytechnic Institute
Timothy J. Boyle, Ph.D., University of Kansas
Andrew Bradbury, Ph.D., Trinity College, University of Cambridge, UK
Forrest B. Brown, Ph.D., University of Michigan
Lee F. Brown, Ph.D., University of Delaware
Susan M. Brozik, Ph.D., Washington State University
Laura J. Frink, Ph.D., University of Illinois
Nancy Jackson, Ph.D., University of Texas
R. Barry King, M.S., University of Houston
Richard C. Martineau, Ph.D., University of Idaho
Thomas M. Mayer, Ph.D., Pennsylvania State University
Patrick J. McDaniel, Ph.D., Purdue University
Warren “Pete” F. Miller Jr., Ph.D., Northwestern University
Jim E. Morel, Ph.D., University of New Mexico
David Stein, Ph.D., University of New Mexico
Chung-Yi Tsai, Ph.D., Worcester Polytechnic Institute
Frank van Swol, Ph.D., University of Amsterdam
James S. Warsa, Ph.D., University of New Mexico

* Registered Professional Engineer in New Mexico.


Overview

The Department of Chemical and Nuclear Engineering (CHNE) offers two undergraduate degree programs, one in chemical engineering and one in nuclear engineering. General department policy on admissions and grading are listed below, followed by detailed descriptions of the two degree programs.

Mission Statement

The B.S. programs in the Department of Chemical and Nuclear Engineering will provide an outstanding education that prepares students to be productive and responsible members of society, with the skills and knowledge to be successful in their professional careers or post-graduate studies. This will be accomplished by engaging students in a variety of academic, research and service activities, and fostering a learning environment that is supportive for a body of students that is diverse in terms of age, gender, ethnicity, and prior educational background.


Admission to Baccalaureate Programs

To earn a baccalaureate degree in chemical or nuclear engineering, a student must apply to and be admitted to the respective baccalaureate program in the Department of Chemical and Nuclear Engineering. For students who have entered the University of New Mexico as freshmen, application to the department’s programs is typically made in the sophomore year. In most cases, such students will have been admitted to the School of Engineering as pre-majors (see “Admission to the School of Engineering” in the School of Engineering section of this catalog). Transfer students may apply to the department’s baccalaureate programs as soon as they have met the program admission requirements discussed below. The department strongly encourages all students who are interested in entering either the baccalaureate program in chemical or in nuclear engineering to apply to the department as soon as they are eligible, to ensure that they receive the proper advisement.

The criteria for admission to the Baccalaureate Programs in Chemical Engineering and Nuclear Engineering are specified in detail in the respective advisement brochures, which may be obtained from the department. There are 18 semester hours of Freshman year technical subjects required by the School of Engineering for admission, and a minimum grade point average of 2.50 in those courses is required for admission to undergraduate study in either Chemical or Nuclear Engineering. A total of 26 semester hours applicable to a degree is required for admission with a grade point average of at least 2.20. All applicants must have completed English 101 or its equivalent before admission. All courses required in a Baccalaureate degree program in the CHNE department must have grades of C- or better for satisfying both admission and graduation requirements.


Policy on D or D+ Grades

Students admitted or readmitted to the Chemical or Nuclear Engineering degree programs may not apply a course toward the B.S. degree in Chemical or Nuclear Engineering if the highest grade earned in the course is a D+ or less, regardless of where that grade was earned.


Courses

CHNE 101. Introduction to Chemical Engineering and Nuclear Engineering. (1)



CHNE 213. Laboratory Electronics for Chemical and Nuclear Engineers. (3)



CHNE 230. Principles of Radiation Protection. (3)



CHNE 231. Principles of Nuclear Engineering. (3)



CHNE 251. Chemical Process Calculations I. (3)



CHNE 253. Chemical Process Calculations II. (3)



CHNE 302. Chemical Engineering Thermodynamics. (4)



CHNE 310. Neutron Diffusion Theory. (3)



CHNE 311. Introduction to Transport Phenomena. (4)



CHNE 312. Unit Operations. (3)



CHNE 313L. Introduction to Laboratory Techniques for Nuclear Engineering. (3)



CHNE 314. Thermodynamics and Nuclear Systems. (3)



CHNE 317. Chemical and Nuclear Engineering Analysis. (3)



CHNE 318L. Chemical Engineering Laboratory I. (1)



CHNE 319L. Chemical Engineering Laboratory II. (1)



CHNE 321. Mass Transfer. (3)



CHNE **323L. Radiation Detection and Measurement. (3)



CHNE *330. Nuclear Engineering Science. (2)



CHNE 361. Biomolecular Engineering. (3)



CHNE 371. Introduction to Materials Engineering. (3)



CHNE 372. Nuclear Materials Engineering. (2)



CHNE 403 / 503. Heterogeneous Catalysis Seminar. (2 to a maximum of 20 Δ)



CHNE 404 / 504. Nanomaterials Seminar. (2 to a maximum of 20 Δ)



CHNE 405 . High Performance Engines. (3)



CHNE 406 / 506. Bioengineering Seminar. (2 to a maximum of 20 Δ)



CHNE *410. Nuclear Reactor Theory I. (3)



CHNE *413L. Nuclear Engineering Laboratory. (3)



CHNE 418L. Chemical Engineering Laboratory III. (1)



CHNE 419L. Chemical Engineering Laboratory IV. (2)



CHNE 432. Introduction to Medical Physics. (3)



CHNE 436 / 536. Biomedical Technology. (3)



CHNE 439 / 539. Radioactive Waste Management. (3)



CHNE 449 . Seminar in Hazardous Waste Management. (1, no limit Δ)



CHNE 451 / 452. Senior Seminar. (1, 1)



CHNE 454. Process Dynamics and Control. (3)



CHNE **461. Chemical Reactor Engineering. (3)



CHNE 462. Monte Carlo Techniques for Nuclear Systems. (3)



CHNE 464 / 564. Thermal-Hydraulics of Nuclear Systems. (3)



CHNE *466. Nuclear Environmental Safety Analysis. (3)



CHNE 468 / 568 . Introduction to Space Nuclear Power. (3)



CHNE 470. Nuclear Fuel Cycle and Materials. (3)



CHNE *475. Polymer Science and Engineering. (3)



CHNE *476. Nuclear Chemical Engineering. (3)



CHNE 477 / 577. Electrochemical Engineering. (3)



CHNE *485. Fusion Technology. (3)



CHNE 486 / 586. Statistical Design of Experiments for Semiconductor Manufacturing. (3)



CHNE 491 – 492. Undergraduate Problems. (1-3 to a maximum of 6 Δ)



CHNE 493L. Chemical Engineering Design. (3)



CHNE 494L. Advanced Chemical Engineering Design. (3)



CHNE 495 – 496. Chemical and Nuclear Engineering Honors Problems I and II. (1-6, 1-6 to a maximum of 6 Δ)



CHNE *497L. Introduction to Nuclear Engineering Design. (3)



CHMS 498L. Nuclear Engineering Design. (4)



CHNE 499. Selected Topics. (1-3, no limit Δ)



CHNE 501. Chemical and Nuclear Engineering Seminar. (1, no limit Δ)



CHNE 502. Chemical and Nuclear Engineering Research Methods Seminar. (1)



CHNE 503 - 403. Heterogeneous Catalysis Seminar. (2 to a maximum of 20 Δ)



CHNE 504 / 404. Nanomaterials Seminar. (2 to a maximum of 20 Δ)



CHNE 506 / 406. Bioengineering Seminar. (2 to a maximum of 20 Δ)



CHNE 507 . Surface and Material Engineering. (2 to a maximum of 20 Δ)



CHNE 508 . Nuclear Engineering Seminar. (2 to a maximum of 20 Δ)



CHNE 511. Nuclear Reactor Theory II. (3)



CHNE 512. Characterization Methods for Nanostructures. (3)



CHNE 513L. Nuclear Engineering Laboratory II. (1 to a maximum of 4 Δ)



CHNE 515. Special Topics. (1-3, no limit Δ)



NONE 516. Medical Imaging I-X-ray Physics. (3)



CHNE 518. Synthesis of Nanostructures. (3)



CHNE 519. Medical Imaging II - MR, Ultrasound and Nuclear Medicine Physics. (3)



CHNE 519L. Medical Imaging Laboratory II - MR, Ultrasound and Nuclear Imaging Physics. (1)



CHNE 520. Radiation Interactions and Transport. (3)



CHNE 521. Advanced Transport Phenomena I. (3)



CHNE 522L. Fundamentals of Nanofluidics. (3)



CHNE 523L. Environmental Measurements Laboratory. (1 to a maximum of 4 Δ)



CHNE 524. Interaction of Radiation with Matter. (3)



CHNE 525. Methods of Analysis in Chemical and Nuclear Engineering. (3)



CHNE 526. Advanced Analysis in Chemical and Nuclear Engineering. (3)



CHNE 527. Radiation Biology for Engineers and Scientists. (3)



CHNE 528. External Radiation Dosimetry. (3)



CHNE 529. Internal Radiation Dosimetry. (3)



CHNE 530. Surface and Interfacial Phenomena. (3)



CHNE 531. Nanoscale Quantum Structure Growth and Device Applications. (3)



CHNE 536 / 436. Biomedical Technology. (3)



CHNE 539 / 439. Radioactive Waste Management . (3)



CHNE 540. Radiation Oncology Physics. (3)



CHNE 541L. Radiation Oncology Physics Laboratory. (3)



CHNE 542. Advanced Chemical Engineering Thermodynamics. (3)



CHNE 546. Charged Particle Beams and High Power Microwaves [Charged Particle Beams.] . (3 to a maximum of 9 Δ)



CHNE 550. Social and Ethical Issues in Nanotechnology. (1-3, [3])



CHNE 551 – 552. Problems. (1-3, 1-3 each semester Δ)



CHNE 560. Nuclear Reactor Kinetics and Control. (3)



CHNE 561. Kinetics of Chemical Processes. (3)



CHNE 563. Advanced Radiation Shielding. (3)



CHNE 564 / 464. Thermal-Hydraulics of Nuclear Systems. (3)



CHNE 568 / 468. Introduction to Space Nuclear Power. (3)



CHNE 575. Selected Topics in Material Science. (1-3, no limit Δ)



CHNE 576. Selected Topics in Aerosol Science. (3 to a maximum of 6 hours Δ)



CHNE 577 / 477. Electrochemical Engineering. (3)



CHNE 582. Inertial Confinement Fusion. (3)



CHNE 586 / 486. Statistical Design of Experiments for Semiconductor Manufacturing. (3)



CHNE 591. Practicum. (6)



CHNE 599. Master’s Thesis. (1-6, no limit Δ)



CHNE 610. Advanced Nuclear Reactor Theory. (3)



CHNE 699. Dissertation. (3-12, no limit Δ)



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Office of the Registrar

MSC 11 6325
1 University of New Mexico
Albuquerque, NM 87131

Phone: (505) 277-8900
Fax: (505) 277-6809