In the M.S. program in Chemical Engineering, students will work side-by-side with world-renowned experts to conduct original research to address global challenges using chemical engineering principles. Our program equips students with a diverse skill set essential for the next generation of chemical engineering leaders in academia and industry. Our students are involved in a wide range of innovative research areas, including, advanced polymeric materials, bioanalytical devices, biomedical science and engineering, systems biology, synthetic biology, and biomanufacturing. 

There are abundant opportunities for collaboration with various departments across the University, including departments in the Colleges of Engineering, Natural Sciences, Veterinary Medicine and Biomedical Sciences, and beyond. 

The Plan A degree is completed with a thesis and satisfactory performance on a final comprehensive examination approved by the student’s graduate committee.

Students interested in graduate work should refer to the Graduate and Professional Bulletin.

Learning Objectives

Upon successful completion of this program, students will be able to:

  1. Demonstrate technical mastery of the core chemical engineering disciplines of thermodynamics, transport phenomena, and chemical reaction engineering. 
  2. Conduct original research in chemical engineering and related fields by assembling a body of new knowledge that advances the field, to achieve significant research objectives.
  3. Maintain high standards of scholarly excellence and responsible research conduct. 
  4. Competently and professionally communicate their research in both written and oral forms. 
  5. Effectively contribute to a broader research endeavor by directly collaborating with other scientists and engineers, or by conducting and communicating their work in such a way that their individual contributions are readily assimilated with the work of other researchers in their field and related fields. 

Effective Fall 2025

Core Courses:8-13
CBE 693
Research Conduct and Practices
Option (1): chemical engineering principles and mathematical modeling12
CBE 501
Chemical Engineering Thermodynamics
CBE 502
Advanced Reactor Design
CBE 503
Transport Phenomena Fundamentals
CBE 521
Mathematical Modeling for Chemical Engineers
OR Option (2): chemical and biological engineering principles 17
CBE 500
Chem & Biological Engineering Fundamentals
CBE 504/BIOM 504
Fundamentals of Biochemical Engineering
Advanced Mathematics, Statistics, and Data Science 10-3
BIOM 422
Quantitative Systems and Synthetic Biology
BIOM 526/ECE 526
Biological Physics
BIOM 537/ECE 537
Biomedical Signal Processing
BIOM 570/MECH 570
Bioengineering
BIOM 576/MECH 576
Quantitative Systems Physiology
BZ 548
Theory of Population and Evolutionary Ecology
BZ 562
Computational Approaches in Molecular Ecology
CS 528/ECE 528
Embedded Systems and Machine Learning
CS 535
Big Data
CS 540
Artificial Intelligence
CS 545
Machine Learning
DSCI 445
Statistical Machine Learning
DSCI 511
Genomics Data Analysis in Python
DSCI 512
RNA-Sequencing Data Analysis
ENGR 478
Applied Engineering Data Analytics
ERHS 535
R Programming for Research
HORT 579
Mass Spectrometry Omics-Methods and Analysis
MIP 545
Microbial Metagenomics/Genomics Data Analysis
MIP 570
Functional Genomics
SOCR 545
Current Methods in Microbial Genomics
STAR 511
Design and Data Analysis for Researchers I
STAR 512
Design and Data Analysis for Researchers II
STAT 520
Introduction to Probability Theory
STAT 540
Data Analysis and Regression
STAT 544/ERHS 544
Biostatistical Methods for Quantitative Data
STAT 547/CIVE 547
Statistics for Environmental Monitoring
STAT 560
Applied Multivariate Analysis
SYSE 541
Engineering Data Design and Visualization
Biomolecular Engineering Electives 10-6
CBE 522/BIOM 522
Bioseparation Processes
CBE 524
Bioremediation
CBE 540/CIVE 540
Advanced Biological Wastewater Processing
CBE 560
Engineering of Protein Expression Systems
CBE 570
Biomolecular Engineering/Synthetic Biology
Biomolecular Engineering Laboratory 10-1
CBE 505
Biochemical Engineering Laboratory
Electives 21-6
5XX - 7XX courses with the course following prefixes: CBE, BIOM, MSE, CIVE, ECE, MECH, SYSE, ENGR, AB, AHS, ANEQ, BC, BMS, BTEC, BZ, CM, CHEM, CS, DSCI, ECOL, ESS, ERHS, FSHN, FTEC, GEOL, GES, GRAD, HORT, LIFE, MATH, MIP, NB, PH, SOCR, STAR, STAA, STAT
Thesis (maximum) 311
CBE 699Thesis11
Program Total Credits30

A minimum of 30 credits are required to complete this program. 

1

Students who choose option (2) in the core courses must take 3 credits in Advanced Statistics and Data Science, 6 credits in Biomolecular Engineering Electives, and 1 credit in Biomolecular Engineering Laboratory

2

For students who choose option (1) in the core courses, take a minimum of 6 credits of electives, including any additional courses in the categories listed above.

For students who choose option (2) in the core courses, take a minimum of 1 credits of electives, including any additional courses in the categories listed above

3

A maximum of 11 thesis research credits (CBE 699) may be counted toward the degree requirements.

Department Seminar Attendance

Master of Science Students are also required to attend the department seminars whenever they are held as a condition of making satisfactory progress towards their degree, except when regular coursework conflicts with the time. 

Examinations and Thesis

An acceptable thesis must be submitted to and approved by the student’s graduate committee. Satisfactory performance on a final comprehensive examination administered by the student’s graduate committee is required. The final comprehensive examination includes an oral presentation of the thesis that is open to the public. It is expected that the student’s M.S. research will result in the submission in at least one refereed publication or other high caliber technical publication. 

For more information, please visit Requirements for All Graduate Degrees in the Graduate and Professional Bulletin.

Summary of Procedures for the Master's and Doctoral Degrees

NOTE:  Each semester the Graduate School publishes a schedule of deadlines. Deadlines are available on the Graduate School website. Students should consult this schedule whenever they approach important steps in their careers.

Forms are available online.

Step Due Date
1. Application for admission (online) Six months before first registration
2. Diagnostic examination when required Before first registration
3. Appointment of advisor Before first registration
4. Selection of graduate committee Before the time of fourth regular semester registration
5. Filing of program of study (GS Form 6) Before the time of fourth regular semester registration
6. Preliminary examination (Ph.D. and PD) Two terms prior to final examination
7. Report of preliminary examination (GS Form 16) - (Ph.D. and PD) Within two working days after results are known
8. Changes in committee (GS Form 9A) When change is made
9. Application for Graduation (GS Form 25) Refer to published deadlines from the Graduate School Website
9a. Reapplication for Graduation (online) Failure to graduate requires Reapplication for Graduation (online) for the next time term for which you are applying
10. Submit thesis or dissertation to committee At least two weeks prior to the examination or at the discretion of the graduate committee
11. Final examination Refer to published deadlines from the Graduate School Website
12. Report of final examination (GS Form 24) Within two working days after results are known; refer to published deadlines from the Graduate School website
13. Submit a signed Thesis/Dissertation Submission Form (GS Form 30) to the Graduate School and Submit the Survey of Earned Doctorates (Ph.D. only) prior to submitting the electronic thesis/dissertation Refer to published deadlines from the Graduate School website.
14. Submit the thesis/dissertation electronically Refer to published deadlines from the Graduate School website
15. Graduation Ceremony information is available from the Graduate School website