Undergraduate Chemical Engineering

Chemical Engineering

Undergraduate Advisor
Abhaya K. Datye

Introduction

The principles and approaches that make up chemical engineering are rooted in the world of atoms, molecules and molecular transformations, and chemical engineers have been leaders in extending our ability to manipulate materials on the atomic scale. Chemical engineers are on the forefront of rapidly developing areas that include biotechnology and biomedicine, semiconductor manufacturing and data storage devices, and advanced materials with precisely-controlled nanostructures. Chemical engineering is a rapidly evolving discipline that offers the excitement of developing cutting-edge products and the satisfaction of making important contributions to technology that improves our lives. Chemical engineering has a rich history of contributions to the nation’s technology base for production of chemicals and materials for consumer products and basic commodities. Chemical engineers have long played key roles in a diverse set of industries that include petroleum, food, pharmaceuticals, artificial fibers, petrochemicals, plastics and ceramics, to name a few. In these areas, chemical engineers design and develop the processes for large-scale manufacturing that result in affordable products that are essential to our way of life. Chemical engineers also work in the areas of environmental protection and remediation, process safety and hazardous waste management.

The diverse applications of chemical engineering, as well as the ability of chemical engineers to be on the leading edge of new fields, derive from the breadth of the chemical engineer’s education. The chemical engineering curriculum at the University of New Mexico offers broad training in the fundamentals of mathematics, physics, chemistry and the engineering sciences. These are integrated with the chemical engineering “core” which includes: thermodynamics, heat, momentum and mass transport, chemical reaction engineering, design, and process control.

Students choose electives which are grouped into concentrations to provide expertise in specific areas. A concentration consists of three advanced chemistry courses and three technical electives. Concentrations include chemical process engineering, bioengineering, materials processing, semiconductor manufacturing, and environmental engineering.

Undergraduate chemical engineering students benefit greatly from the extensive research activities of our faculty in strategic areas of chemical engineering. The research activities are well integrated and supportive of our teaching mission and have enabled us to continually improve the quality of our laboratory courses. A significant number of undergraduates participate in one-on-one research projects with individual faculty, often focused on the student’s area of concentration. The nearby national laboratories provide additional opportunities for student research. Learning is enhanced with such hands-on experience, and students are more competitive when they leave the University of New Mexico. Our research activities have allowed us to develop new courses and to alter the content of existing courses to incorporate state-of-the-art knowledge and practice.

The chemical engineering graduate will find many avenues of opportunity in chemical processing, food and consumer products, fibers and textiles, biotechnology, advanced materials, semiconductor manufacturing, environmental protection and remediation and other vital industries. Extensive opportunities also exist for students desiring to work towards advanced degrees in the field. And finally, a chemical engineering undergraduate degree represents an excellent foundation for an advanced professional degree in medicine, business or law.

Graduates of the undergraduate program in Chemical Engineering will be successfully progressing in their careers or post-graduate endeavors in diverse chemical engineering areas, including chemical process engineering, biomedical engineering, materials processing, semiconductor manufacturing, and environmental engineering, by:

demonstrating technical competence,
solving technical problems efficiently, and
communicating effectively in both written and oral forms.

The most up-to-date version of the objectives is available at the web site (http://www-chne.unm.edu/).

Curriculum in Chemical Engineering

The Bachelor of Science Program in Chemical Engineering is accredited by the Engineering Accreditation Commission of ABET, 111 Market Place, Suite 1050, Baltimore, MD 21202-4012 - telephone (410) 347.7700.

Hours required for graduation: 132 (9)

First Year	First Semester	Hrs. Cr.
CHNE 101	Introduction to Chemical Engineering and Nuclear Engineering	1
MATH 162	Calculus I	4
CHEM 121	General Chemistry	3
CHEM 123L	General Chemistry Lab	1
ENGL 101	Composition I: Exposition	3
	Core Humanities Elective (3)	3
		15
	Second Semester
MATH 163	Calculus II	4
CHEM 122	General Chemistry II	3
CHEM 124L	General Chemistry II Lab	1
CS 151L	Computer Programming Fundamentals for Non-Majors/Lab	3
ENGL 102	Composition II: Analysis and Argument	3
PHYC 160	General Physics	3
		17
Second Year	First Semester
CHNE 251	Chemical Process Calculations I	3
MATH 264	Calculus III	4
CHEM 301	Organic Chemistry	3
CHEM 303L	Organic Chemistry/Laboratory	1
PHYC 161	General Physics	3
ECON 105	Introductory Macroeconomics⁽⁴⁾	3
		17
	Second Semester
CHNE 253	Chemical Process Calculations II	3
CHNE 302	Chem Engr Thermodynamics	4
MATH 316	Applied Ordinary Differential Equations	3
	Basic Science for Concentration (5)	3
	Adv Chem for Concentration (6)	3
		16
Third Year	First Semester
CHNE 311	Introduction to Transport Phenomena	4
CHNE 317	Chemical and Nuclear Engineering Analysis	3
CHNE 318L	Chemical Engr Lab I	3
CHNE 361	Biomolecular Engr	3
ENGL 219	Technical and Professional Writing (4)	3
	Adv Chem for Concentration (6)	3
		17
	Second Semester
CHNE 312	Unit Operations	3
CHNE 321	Mass Transfer	3
CHNE 319L	Chemical Engineering Lab II	1
CHNE 371	Intro Materials Engr	3
	Basic Engineering Elective (7)	3
	Adv Chem for Concentration⁽⁶⁾	3
		16
Fourth Year	First Semester
CHNE 418L	Chemical Engineering Lab III	1
CHNE 451	Senior Seminar	1
CHNE 461	Chemical Reactor Engineering	3
CHNE 493L	Chemical Engineering Design	3
	Technical Elective (8)	3
	Core Humanities Elective⁽³⁾	3
	Core Social/Behavior Science Elective⁽³⁾	3
		17
	Second Semester
CHNE 419L	Chemical Engineering Lab IV	2
CHNE 454	Process Dynamics and Control	3
CHNE 494L	Advanced Chemical Engr Design	3
	Technical Elective (8)	3
	Core Fine Arts Elective (3)	3
	Core Second Language Elective (3)	3
		17

Footnotes:

^{Only courses with grades of C- or better may be applied toward the bachelor of science degree in chemical engineering.}
^{Students must file and application for the B.S. degree prior to the completion of 95 semester hours of applicable courses.}
^{Students should consult with advisors to obtain a list of acceptable core humanities, social/behavioral science, fine arts and second language electives. These courses may be taken whenever convenient. Grade must be C- or better.}
^{ECON 105 and ENGL 219 may be taken in either the sophomore or junior year.}
^{PHYC 262 or BIOL 201, depending on the student's area of concentration.}
^{A minimum of 9 credit hours of advanced chemistry, selected from among CHEM 302, 311, 312, 421, 431, or BIOC 423, depending upon the student's area of concentration. For illustrative purposes, the Spring semester Sophomore Year curriculum is shown assuming CHEM 302 as the advanced chemistry concentration. Other advanced chemistry courses may be substituted. One semester of Physical Chemistry is required for all concentrations. Up to four hours of other natural science courses may be substituted for advanced chemistry. Such advanced natural science courses must build on basic science prerequisites and may include physics, life sciences, and material science. The courses chosen must represent a logical sequence of courses for the concentration and must be approved by the academic advisor.}
^{Recommended course CHNE 213. Alternatives are CE 202, CE/ME 304 or ECE 203. Students in the semiconductor processing concentration may wish to take ECE 203.}
^{Technical electives are chosen from approved upper-division courses in engineering, mathematics and science. The department requires that these courses be part of an approved concentration. The chairperson may allow up to 6 hours of technical electives for students taking required ROTC courses in aerospace or naval science.}
^{Students are encouraged to take the Fundamentals of Engineering (FE) Examination during their senior year. This is the first formal step toward professional registration.}

Persons having special needs and requiring auxiliary aid or service should contact the Department of Chemical and Nuclear Engineering (ADA and Rehabilitation Act of 1973).

Chemical Engineering Concentrations

Future chemical engineers will conceive and solve problems on a range of scales (nano, micro and macro). They will bring new tools and insights from research and practice in other disciplines: molecular biology, chemistry, solid-state physics, materials science, and electrical engineering. They will also make increasing use of computers, artificial intelligence and expert systems in problem solving, in product and process design, and in manufacturing. Chemical engineering can be viewed as the engineering discipline with the strongest tie to the molecular sciences and therefore is an integral part of multidisciplinary research efforts. To allow students an opportunity to gain in-depth knowledge in specialized areas and to prepare them for diverse career opportunities, we provide five concentrations:

Chemical Process Engineering
Bioengineering
Materials Processing
Semiconductor Manufacturing
Environmental Engineering

Students choose a basic engineering elective, a basic science elective, 3 advanced chemistry courses and two technical electives. In addition to these courses, the projects in the last design course (494L) and the last laboratory course (419L) provide opportunities to gain experience in the chosen concentration.

Basic Engineering Elective
The recommended course is CHNE 213. Alternatives are CE 202 or ECE 203. Students in the semiconductor processing concentration may wish to take ECE 203.

Basic Science Elective
Students in Bioengineering or Environmental Engineering concentrations will take Biology 201, all others take Physics 262 during the second semester of the sophomore year. Biology 201 is also an option for students in the Materials Processing Concentration interested in organic, polymeric or biomedical materials.

Advanced Chemistry and Sciences Electives
A minimum of 9 credit hours of advanced chemistry, selected from among CHEM 302, 304L, 311, 312, 421, 431, or BIOC 423, depending upon the student’s area of concentration. One semester of Physical Chemistry is required for all concentrations. Up to four hours of other natural science courses may be substituted for advanced chemistry. Such advanced natural science courses must build on basic science prerequisites and may include physics, life sciences, and material science. The courses chosen must represent a logical sequence of courses for the concentration and must be approved by the academic advisor.

Technical Electives
Students have the opportunity to take 6 credit hours of technical electives. Three hours must be engineering courses within the department or the school. The other three hours may be taken outside of the school but must be a logical part of the concentration.

Chemical Process Engineering Concentration

The Chemical Process Engineering concentration is designed to provide maximum flexibility for students to pursue career opportunities in a wide range of industries as a process engineer. Historically, many chemical process engineers have found employment in the petroleum or chemical industries, and many still do. However, chemical engineers with a strong process engineering foundation are in increasing demand in many other technology areas, including pharmaceuticals, semiconductors and electronic materials, and environmental or “green” engineering. This concentration builds on the traditional process engineering emphasis, allowing the technical electives to be chosen by the student in consultation with his adviser to fit the interests or professional goals of the student.

	Basic Science Elective
PHYC 262	General Physics	3
	Advanced Chemistry and Science Electives
CHEM 302	Organic II	3
CHEM 311	Physical Chemistry I	3
CHEM 312	Physical Chemistry II	3
	Technical Electives
	Technical Elective	3
	Technical Elective (Engr)	3

Bioengineering Concentration

Since biological and medical systems involve complex chemical and physical processes, chemical engineering is a natural professional background for bioengineering applications. Bioengineering is an interdisciplinary field that combines the tools and methods of engineering to address challenges in the health sciences and in basic research. Bioengineers strive to understand biological systems, from molecules to whole organisms, from a quantitative and analytical perspective. Because of this in-depth study, bioengineers are uniquely qualified to work at the interface between living and non-living systems, enhancing our ability to measure, image, repair, or replace physiological substances or processes. Training in bioengineering prepares students for graduate school or industry, and is an excellent preparation for professional programs (medicine, dentistry, nursing, pharmacy). Career opportunities for bioengineers at the B.S. level include the biosensor, pharmaceutical and medical device industries as well as positions in hospitals, federal labs, and environmental agencies.

	Basic Science Elective
BIOL 201	Cell Biology	4
	Advanced Chemistry and Science Electives
CHEM 302	Organic II	3
CHEM 312	Physical Chemistry	3
	Advanced Biology*	3
	Technical Electives
	Technical Elective	3
	Technical Elective (Engr)	3

*Typical choices for the advanced biology courses would be BIOL 202, 237, 238, 239L, BIOC 423 or CHEM 421.

Materials Processing Concentration

The Materials Processing concentration is designed to add additional emphasis in inorganic materials, polymeric, or biological materials, depending on the students interest. Students who are interested in working in the realm of high technology materials, biomedical materials, or nanotechnology should choose this concentration. These rapidly developing fields are expected to provide many job opportunities in the next decade. New materials are currently being developed whose properties depend strongly on their microstructure, nanostructure and processing history. Materials included in this category are advanced ceramics, polymers, composites, photonics, superconductors, semiconductors, and recording media. This concentration provides flexibility for students interested in inorganic or organic materials technology.

	Basic Science Elective
PHYC 262	General Physics or
BIOL 201	Cell Biology	3
	Advanced Chemistry and Science Electives
CHEM 311	Physical Chemistry I	3
CHEM 312	Physical Chemistry II	3
CHEM 431	Adv Inorganic Chem or
CHNE 475	Polymer Science and Eng	3
	Technical Electives
	Technical Elective	3
	Technical Elective (Engr)	3

Semiconductor Manufacturing Concentration

There is an increasing demand for chemical engineers in high technology oriented semiconductor manufacturing companies like Intel, Motorola, IBM, etc. This concentration is designed to prepare the student in the fundamental unit operations used in semiconductor manufacturing (oxidation, diffusion, lithography, plasma etch, CVD, ion implant and metalization) and statistical methods used extensively in the industry to optimize the performance of these unit operations. The continuing revolution occurring in computer technology virtually insures there will be a strong future demand for engineers with the background needed for semiconductor manufacturing. The goal of this concentration is to introduce students to the specific chemical engineering tools used in micro-chip fabrication.

	Basic Science Elective
PHYC 262	General Physics	3
	Advanced Chemistry and Science Electives
CHEM 311	Physical Chemistry I	3
CHEM 312	Physical Chemistry II	3
CHEM 431	Adv Inorganic Chem	3
	Technical Electives
ECE 371	Materials and Devices	4
	Technical Elective	3

Environmental Engineering Concentration

The chemical engineer with a concentration in waste management will be prepared to enter a field of growing importance. This field deals with treatment of waste to reduce its volume, to recover recyclable resources and to prepare appropriately for long-term disposal. Interesting applications exist in atmospheric discharge control and clean-up, bio-treatable water decontamination, soil remediation, and nuclear byproduct handling. Increasingly, chemical engineers will be required to develop new processes to minimize byproduct and waste generation, and achieve higher energy efficiencies.

	Basic Science Elective
BIOL 201	Cell Biology	4
	Advanced Chemistry and Science Electives
CHEM 302	Organic II	3
CHEM 312	Physical Chemistry	3
BIOC 423	Introductory Biochemistry or Advanced Biology*	3
	Technical Electives
	Technical Elective	3
	Technical Elective(Engr)	3

*Typical choices for advanced biology would be BIOL 202, 237, 238, 204L, 239L, 423, or CHEM 421

Chemical Engineering Laboratory

The chemical engineering laboratory is equipped with pilot plant equipment for the study of heat and mass and momentum transfer including the unit operations: liquid-liquid extraction, multitube heat exchangers, evaporation, distillation and absorption. Experiments also exist for the engineering sciences: thermodynamics, chemical kinetics, fluid mechanics and process control. Automated engineering workstations for data acquisition and control are an integral part of the laboratory. For juniors and seniors, opportunities exist for research projects in the following areas: catalysis, semiconductor manufacturing, fuel cells, biosensors, aerosol synthesis of materials, chemical vapor deposition and plasma etching. Students undertaking individual research projects gain exposure to state of the art analytical equipment such as ellipsometry, scanning and transmission electron microscopy, Auger spectroscopy, x-ray photoelectron spectroscopy, IR and UV spectroscopy, and x-ray scattering.

Computer Facilities

Computers provide the basic computational tool for today’s modern engineer. The department maintains a computer pod equipped with state-of-the-art computers. Additional computers are available in the many University of New Mexico computer pods maintained by the University of New Mexico’s Computer and Information Resources and Technology division. Freshman engineering students are introduced to the many computer facilities and to programming. Numerical analysis is an important part of each year’s instruction in chemical engineering, and by the senior year students make extensive use of sophisticated process simulation codes, and learn to write digital process control programs. Students interested in working in the semiconductor industry or advanced materials can gain extensive experience with software tools for statistical design of experiments. In addition to these technical software packages, students also gain experience with mathematical packages such as spreadsheets and symbolic manipulation software.

Honors Program

Eligible freshmen and upperclassmen in the Department of Chemical and Nuclear Engineering are urged to enroll in the Honors Program. Chemical and nuclear engineering students may graduate with General Honors (honors in general studies), with Departmental Honors or both. Information is available from departmental advisors and the University Honors Center.

Cooperative Education

Chemical engineering students may participate in the cooperative education program or in summer industrial internship programs. Excellent opportunities exist throughout the southwest for undergraduate chemical engineering students. For further information, refer to Section III: Cooperative Education Program in this catalog, or contact the Director of Career Services.

Keys and Symbols Reference