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Curriculum in Chemical Engineering
Chemical engineers are concerned with
the application of knowledge gained from basic sciences and practical
experience to the development, design, operation and management
of plants and processes for economical and safe conversion of
chemical raw materials to useful products. Because chemical engineering
is the most broadly based of all engineering disciplines, the
chemical engineer is in great demand in diverse technical and
supervisory areas in a wide variety of industries, and has consistently
commanded one of the highest starting salaries of all college
graduates.
In addition to dominating the extensive
chemical, petroleum and petrochemical industries, for which the
Texas Gulf Coast is the nation's leading region, chemical engineers
are leaders in such areas as food and pharmaceutical processing,
biochemical and biomedical engineering, pollution control and
abatement, polymers and plastics, ceramics and other advanced
materials, corrosion control, automation and instrumentation,
aerospace and nuclear materials, computer technology and data
processing, safety, environmental control, and many others.
The versatility of the chemical engineer
stems directly from a broad fundamental training in basic chemical
and physical sciences as well as a wide variety of engineering
disciplines. Besides a heavy emphasis on chemistry and mathematics,
the curriculum includes training in physics, economics, humanities
and communication skills. The course work in chemical engineering
provides balanced training in virtually all aspects of chemical
engineering principles and practice. Courses in the department
are specifically designed to emphasize fundamentals which are
applicable to the analysis, development, design and operation
of a wide variety of systems and processes, rather than technological
details and rote solution of numerous routine problems.
It is this philosophy which has enabled
the graduate chemical engineer to adapt readily to a dynamic
and rapidly evolving technology and to solve problems he or she
has not previously experienced. To supplement the course work,
the department is well equipped with modern laboratories where
the student can experience the operation and analysis of a variety
of unit operations and process control equipment.
Program objectives are to provide graduates
an educational foundation with sufficient depth and breadth for
(1) successful chemical engineering careers in industry, academia
or government; (2) application and transfer of knowledge across
disciplines and into emerging areas of chemical engineering;
(3) effective communications supported by appropriate leadership
and teaming skills; (4) ethical conduct with a sense of responsibility
to their profession and an appreciation for the impact of their
profession on society.
Admission to upper-level status in chemical
engineering is a prerequisite for enrolling in the chemical engineering
course sequence. Specific academic performance requirements must
also be met for advancement from sophomore to junior and junior
to senior level in the chemical engineering course sequence (the
undergraduate advisor should be consulted for specific requirements).
The two required Chemical Engineering
specialty courses in the senior year provide the student an opportunity
to acquire in-depth knowledge in one or more specialized areas
of chemical engineering practice. These courses extend and apply
the fundamentals developed in the basic courses. The courses
are to be taken from a prescribed list, which includes such topics
as Biotechnology, Environmental Remediation, Materials Engineering,
Microelectronics Processing, Polymer Engineering, Math Models,
etc. Other courses may also be acceptable, with special approval.
This requirement may be met by taking a variety of courses in
different areas, or a sequence of courses with emphasis in a
specific area. Students interested in this option should consult
with an advisor.
The department is fully accredited by
the Engineering Accreditation Commission of the Accreditation
Board for Engineering and Technology and the American Institute
of Chemical Engineers and compares favorably with the best in
the nation.
Sophomore Year
|
First Semester |
(Th-Pr)
|
Cr
|
|
Second Semester |
(Th-Pr)
|
Cr
|
|
CHEM 227 Organic Chemistry I |
(3-0)
|
3
|
|
CHEM 228 Organic Chemistry II |
(3-0)
|
3
|
|
CHEM 237 Organic Chemistry Lab. |
(0-3)
|
1
|
|
CHEM 238 Organic Chemistry Lab. |
(0-3)
|
1
|
|
CHEN 204 Elem. Chemical Engineering |
(2-3)
|
3
|
|
CHEN 205 Chemical Engineering Thermodynamics
I |
(3-0)
|
3
|
|
ENGR 211 Conserv. Prin. of Engr.
Mech. |
(3-0)
|
3
|
|
MATH 308 Differential Equations |
(3-0)
|
3
|
|
MATH 251 Engineering Mathematics
III |
(3-0)
|
3
|
|
Electives |
|
6
|
|
Elective |
|
3
|
|
|
|
16 |
|
|
|
16 |
|
|
|
|
Junior Year
|
CHEM 316 Quantitative Analysis |
(2-0)
|
2
|
|
CHEM 322 Physical Chemistry
for Engineers |
(3-0)
|
3
|
|
CHEM 318 Quantitative Analysis Lab. |
(0-3)
|
1
|
|
CHEM 325 Physical Chemistry Lab.
I |
(0-3)
|
1
|
|
CHEN 304 Chemical Engineering Fluid
Operations |
(3-0)
|
3
|
|
CHEN 323 Chemical Engineering Heat
Transfer Operations |
(3-0)
|
3
|
|
CHEN 320 Chemical Engineering Analysis. |
(3-0)
|
3
|
|
CHEN 354 Chem. Engineering Thermo.
II |
(3-0)
|
3
|
|
ENGR 213 Prin. of Materials Engr. |
(3-0)
|
3
|
|
ENGL 210 Scientific and Tech. Writing |
|
|
|
Elective |
|
3
|
|
or |
|
|
|
Elective |
|
3 |
|
ENGL 301 Technical Writing |
(3-0)
|
3
|
|
|
|
18 |
|
ENGR 215 Prin. of Electrical Engr. |
(3-0)
|
3
|
|
|
|
|
|
|
|
16 |
Senior Year
|
CHEM 326 Physical Chemistry Lab.
II |
(0-3)
|
1
|
|
CHEN 426 Chemical Engineering
Plant Design |
(1-6)
|
3
|
|
CHEN 414 Chemical Engineering Lab.
I |
(0-3)
|
1
|
|
CHEN 433 Chemical Engr. Lab. II |
(0-3)
|
1
|
|
CHEN 424 Chemical Engineering Mass
Transfer Operations |
(3-0)
|
3
|
|
CHEN 464 Chemical Engineering Kinetics |
(3-0)
|
3
|
|
CHEN 425 Chemical Engineering Plant
Economics |
(2-0)
|
2
|
|
CHEN specialty electives |
|
6
|
|
CHEN 455 Process Safety Engr. |
(3-0)
|
3
|
|
Elective |
|
3
|
|
CHEN 461 Proc. Control and Instr. |
(3-3)
|
4
|
|
|
|
16 |
|
CHEN 481 Seminar |
(0-2)
|
1
|
|
|
|
|
|
|
|
15 |
|
|
|
|
Scholastic Performance Requirements for
Chemical Engineering Undergraduates
The Texas A&M
University Student Rules stipulate that a student must
achieve a minimum grade point ratio (GPR) of 2.0 both overall,
as well as in those courses in the major, in order to graduate
from the University. The University also classifies students
with less than 30 credit hours as freshmen (U1), 30 to 60
hours as sophomores (U2), 60 to 94 hours as juniors (U3),
and 95 hours or more as seniors (U4). The Department of Chemical
Engineering imposes additional requirements for students
to be accepted into, and progress through, the Chemical Engineering
curriculum, based upon classification with regard to the
courses which have been completed in the Chemical Engineering
curriculum, as follows.
Freshmen. All students who are classified
as lower level (CHEL) are considered to be freshmen with regard
to the Chemical Engineering curriculum, regardless of the total
number of credit hours that they have earned. Students will
not be permitted to enroll in any Chemical Engineering course
until they have been admitted to upper- level (CHEN) status.
Automatic admission to upper-level status will be granted to
students who complete the Common Body of Knowledge (CBK) courses
in the freshman year of the curriculum (e.g., all of the required
first year English, chemistry, physics, math and engineering
courses), with no grade below a C and a minimum cumulative
GPR of 3.0 in these courses, as well as an overall GPR of 3.0
or higher. Additional admissions to upper level may be made
for students with a GPR below 3.0 in the CBK courses, up to
a maximum of 160 students per year. The departmental advisor
for freshmen is Dr. D. T. Hanson.
Sophomores. Students who have been admitted
to upper-level (CHEN) status, but who have not completed all
200-level
CHEN courses, are classified as Chemical Engineering sophomores
regardless of the total number of credit hours they have earned.
All students are required to complete both CHEN 204 and CHEN
205, each with a grade of C or better, and earn an overall
GPR of 2.5 or higher, before being allowed to enroll in junior
CHEN (300-level) courses. Neither CHEN 204 nor CHEN 205 can
be repeated more than once. The departmental advisor for sophomores
is Dr. Lale Yurttas.
Juniors. Students who have successfully
completed all 200-level CHEN courses, but have not completed
all of the
300-level CHEN courses in the Chemical Engineering curriculum,
are classified as Chemical Engineering juniors regardless of
the total number of credit hours they have earned. Students
must complete each 300-level CHEN course in the Chemical Engineering
curriculum with a grade of C or better, and have a cumulative
average GPR of 2.0 or better for all CHEN courses, before being
permitted to enroll in 400-level CHEN courses. The departmental
advisor for juniors is Dr. Lale Yurttas.
Seniors. Students who have successfully
completed all required 300-level CHEN courses are classified
as Chemical
Engineering seniors. All students must complete each of the
400-level required prerequisite CHEN courses with a grade of
C or better, and have a cumulative average GPR of 2.0 for all
CHEN courses, as well as an overall GPR of 2.0, in order to
qualify for graduation with a B.S. degree in Chemical Engineering.
The departmental advisor for seniors is Dr. Lale Yurttas. Graduating
seniors in their final semester should see Dr. Yurttas for
their final degree checks.
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