Chemical Engineering
Home Department: Chemical Engineering And Materials Science
Department Head:
Susan Farhat, Ph.D.
Program Overview
Chemical engineers apply the principles of chemistry, math, and physics to the design and operation of large-scale chemical manufacturing processes. They translate processes developed in the lab into practical applications for the production of products such as plastics, medicines, detergents, and fuels; design plants to maximize productivity and minimize costs; and evaluate operations for performance and product quality. Due to the diversity seen in the field, chemical engineers have a broad knowledge of engineering science and environmental regulations, and as a consequence are prepared to manage large scale, multi-disciplinary projects.
The BS in Chemical Engineering is designed to prepare graduates with an understanding of advanced chemistry topics; fundamental material and energy balances for chemical processes; thermodynamics; fluid dynamics and heat transfer; chemical reaction engineering; separations and mass transfer technology; and process design, optimization, and control. Students are also exposed to experimental and computational methods related to chemical engineering, in a sequential set of courses beginning in their sophomore year. Many of these laboratory courses require students to work in teams to submit written and oral reports or apply computational software to complete their projects. In their senior year, students take part in a capstone design course which allows them to integrate the knowledge acquired from their prior foundational courses. Throughout the curriculum, process safety and health as well as environmental and ethical issues in engineering are incorporated. Chemical engineering elective courses are designed to expose students to applications of chemical engineering - including polymer science and engineering, sustainable engineering design, battery technology, and process safety.
Graduates of this program are working in a wide range of industries, including petrochemicals, biotechnology, pharmaceuticals, alternative energy, food, electronics, health, automotive, aerospace, and the environment. Many of them work in product and process engineering, research and development, operations, technical sales, engineering systems design, plant or corporate management, and manufacturing. Common minors that complement the BS in Chemical Engineering degree include Sustainability, Business, Manufacturing, PreMed, and Statistics.
Kettering University’s Bachelor of Science in Chemical Engineering is a strong interdisciplinary program that draws on the strengths of our exceptional faculty, curricula, laboratories, and unique co-op component.
The Chemical Engineering program is accredited by the Engineering Accreditation Commission (EAC) of ABET.
Program Educational Objectives
The Chemical Engineering program is designed to provide its graduates a solid educational foundation on which they can build successful and sustainable careers in chemical engineering or a related field. In particular, all graduates of the Chemical Engineering program will:
- Be employed or pursuing an advanced degree in the field of chemical engineering or other related disciplines.
- Be productive members of interdisciplinary teams.
- Assume leadership positions in their industry, their continuing education, or in their communities, as their careers develop.
- Continue their professional development and engage in the life-long learning necessary for a sustainable career.
BS/MASTERS PATHWAY
Undergraduate students also have an opportunity to get their bachelor's and master's degrees in five years with the BS/MASTERS Pathway.
Chemical Engineering Program Curriculum Requirements
| Code | Title | Credit Hours |
|---|---|---|
| First Year Experience | ||
| CILE-101 | First Year Foundations | 1 |
| General Education | ||
| COMM-101 | Rhetoric & Writing | 4 |
| ECON-201 | Economic Principles | 4 |
| 200-level Liberal Arts Electives | 8 | |
| Advanced Humanities or Social Science Electives 1,2 | 8-12 | |
| LA-489 | Senior Seminar: Leadership, Ethics, and Contemporary Issues | 4 |
| Total Credit Hours | 29-33 | |
- 1
Humanities and Social Science advanced electives must be selected from approved 300 and 400 level courses.
- 2
The following programs complete eight credits of Advanced Humanities or Social Science Electives: Chemical Engineering, Computer Engineering, Electrical Engineering, Engineering, Industrial Engineering, and Mechanical Engineering.
The following programs complete 12 credits of Advanced Humanities or Social Science Electives: Computer Science and Management
| Code | Title | Credit Hours |
|---|---|---|
| Basic Sciences | ||
| Select one of the following: | 4 | |
| General Chemistry I and Principles of Chemistry Lab | ||
| Principles of Chemistry and Principles of Chemistry Lab | ||
| CHEM-237 & CHEM-238 | General Chemistry II and General Chemistry II Lab | 4 |
| CHEM-345 & CHEM-346 | Organic Chemistry I and Organic Chemistry I Lab | 6 |
| CHEM-347 | Organic Chemistry II | 4 |
| Advanced Chemistry Elective 3 | 4 | |
| PHYS-114 & PHYS-115 | Newtonian Mechanics and Newtonian Mechanics Laboratory | 4 |
| PHYS-224 & PHYS-225 | Electricity and Magnetism and Electricity and Magnetism Laboratory | 4 |
| Credit Hours Subtotal: | 30 | |
| Mathematics | ||
| MATH-101 | Calculus I | 4 |
| or MATH-101X | Calculus I | |
| MATH-102 | Calculus II | 4 |
| or MATH-102X | Calculus II | |
| MATH-158 | Foundations of Probability & Statistics | 4 |
| MATH-203 | Multivariate Calculus | 4 |
| or MATH-203X | Multivariate Calculus | |
| MATH-204 | Differential Equations & Laplace Transforms | 4 |
| Credit Hours Subtotal: | 20 | |
| Engineering Topics | ||
| ENGR-101 | Computational Thinking | 4 |
| IME-100 | Interdisciplinary Design and Manufacturing | 4 |
| MECH-211 | Circuits and Mechatronics | 4 |
| CHME-200 | Mass & Energy Balance | 4 |
| CHME-207 | Materials Engineering | 4 |
| CHME-210 | Chemical Engineering Thermodynamics | 4 |
| CHME-225 | Computing in Chemical Engineering | 2 |
| CHME-302 | Engineering Safety and Risk Management | 4 |
| CHME-310 | Fluid Dynamics and Heat Transfer | 4 |
| CHME-325 | Fluid Dynamics and Heat Transfer Lab | 2 |
| CHME-330 | Mass Transfer and Separations | 4 |
| CHME-350 | Reaction Engineering | 4 |
| CHME-425 | Separations, Reactions, and Prototyping Lab | 2 |
| CHME-430 | Process Controls | 4 |
| CHME-440 | Senior Chemical Engineering Design I | 4 |
| Credit Hours Subtotal: | 54 | |
| Chemical Engineering Program Electives | ||
| Select 2 of the following: | 8 | |
| Sustainable Engineering Design: Energy and Environment | ||
| Polymer Science & Engineering | ||
| Fundamentals - Battery Systems | ||
| Alternative Fuels | ||
| Chemical Eng. Special Topics | ||
| Electives | ||
| Technical Electives 4 | 8 | |
| Free Electives | 8 | |
| Credit Hours Subtotal: | 24 | |
| Undergraduate Thesis | ||
| CILE-400 & CILE-401 | Undergraduate Thesis Initiation and Undergraduate Thesis Completion 5 | 4 |
| Credit Hours Subtotal: | 4 | |
| Total Credit Hours | 132 | |
(Minimum) Total Credits Required for Program: 1612
- 2
The minimum total number of credit hours required for graduation is 161; however, the total number of credit hours taken may exceed 161. All Chemical Engineering majors must meet the general educational requirements of 29 credits.
- 3
The Advanced Chemistry Elective must be numbered 300 or higher and cannot be Organic Chemistry I or Organic Chemistry II, since these are already required courses.
- 4
A minimum of eight hours of technical electives are required for the Chemical Engineering Degree. A technical elective may be any course numbered 300-599 in BIOL, CE, CHEM, CHME, CS, EE, IME, ISYS, MATH, MECH, or PHYS that is not used to complete core degree requirements. Additional courses that can be used include BUSN-303, BUSN-304, and MGMT-419/619. Other courses may be used but require approval by the Department Head of Chemical Engineering.
- 5
Students are automatically registered for CILE-400 in a co-op term when they reach Junior II status.
Representative Program1,2
| Freshman I | Credit Hours | |
|---|---|---|
| CILE-101 | First Year Foundations | 1 |
| CHEM-135 & CHEM-136 or CHEM-137 |
Principles of Chemistry or General Chemistry I |
4 |
| COMM-101 | Rhetoric & Writing | 4 |
| IME-100 | Interdisciplinary Design and Manufacturing | 4 |
| MATH-101 | Calculus I | 4 |
| Credit Hours | 17 | |
| Freshman II | ||
| CHEM-237 & CHEM-238 |
General Chemistry II and General Chemistry II Lab |
4 |
| ENGR-101 | Computational Thinking | 4 |
| MATH-102 | Calculus II | 4 |
| MATH-158 | Foundations of Probability & Statistics | 4 |
| Credit Hours | 16 | |
| Sophomore I | ||
| CHME-207 | Materials Engineering | 4 |
| ECON-201 | Economic Principles | 4 |
| MATH-203 | Multivariate Calculus | 4 |
| PHYS-114 & PHYS-115 |
Newtonian Mechanics and Newtonian Mechanics Laboratory |
4 |
| Credit Hours | 16 | |
| Sophomore II | ||
| CHEM-345 & CHEM-346 |
Organic Chemistry I and Organic Chemistry I Lab |
6 |
| CHME-200 | Mass & Energy Balance | 4 |
| PHYS-224 & PHYS-225 |
Electricity and Magnetism and Electricity and Magnetism Laboratory |
4 |
| MATH-204 | Differential Equations & Laplace Transforms | 4 |
| Credit Hours | 18 | |
| Junior I | ||
| CHEM-347 | Organic Chemistry II | 4 |
| CHME-210 | Chemical Engineering Thermodynamics | 4 |
| MECH-211 | Circuits and Mechatronics | 4 |
| 200-level Liberal Arts Elective | 4 | |
| Technical Elective 4 | 4 | |
| Credit Hours | 20 | |
| Junior II | ||
| CHME-225 | Computing in Chemical Engineering | 2 |
| CHME-302 | Engineering Safety and Risk Management | 4 |
| CHME-310 | Fluid Dynamics and Heat Transfer | 4 |
| CHME-325 | Fluid Dynamics and Heat Transfer Lab | 2 |
| 200-level Liberal Arts Elective | 4 | |
| Credit Hours | 16 | |
| Senior I | ||
| CHME-330 | Mass Transfer and Separations | 4 |
| CHME-350 | Reaction Engineering | 4 |
| CHME-430 | Process Controls | 4 |
| Advanced Chemistry Elective 3 | 4 | |
| Advanced Humanities or Social ScienceElective 2 | 4 | |
| Credit Hours | 20 | |
| Senior II | ||
| CHME-425 | Separations, Reactions, and Prototyping Lab | 2 |
| CHME-440 | Senior Chemical Engineering Design I | 4 |
| Chemical Engineering Program Elective | 4 | |
| AdvancedHumanities or Social Science Elective 2 | 4 | |
| Technical Elective | 4 | |
| Credit Hours | 18 | |
| Senior III | ||
| LA-489 | Senior Seminar: Leadership, Ethics, and Contemporary Issues | 4 |
| Chemical Engineering Program Elective | 4 | |
| Free Electives | 8 | |
| Credit Hours | 16 | |
| Any Term | ||
| CILE-400 & CILE-401 |
Undergraduate Thesis Initiation and Undergraduate Thesis Completion |
4 |
| Credit Hours | 4 | |
| Total Credit Hours | 161 | |
(Minimum) Total Credits Required for Program: 1611
- 1
The minimum total number of credit hours required for graduation is 161; however, the total number of credit hours taken may exceed 161. All Chemical Engineering majors must meet the general educational requirements of 29 credits.
- 2
Advanced Humanities or Social Science Electives must be selected from approved 300 or 400-level courses.
- 3
The Advanced Chemistry Elective must be numbered 300 or higher and cannot be Organic Chemistry I or Organic Chemistry II, since these are already required courses.
- 4
A minimum of 8 hours of technical electives are required for the Chemical Engineering Degree. A technical elective may be any course numbered 300-599 in BIOL, CE, CHEM, CHME, CS, EE, IME, ISYS, MATH, MECH, or PHYS that is not used to complete core degree requirements. Other courses may be used but require approval by the Department Head of Chemical Engineering.

