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2020-2021

The Undergraduate Calendar

 

 

Faculty of Engineering

Bachelor of Applied Science and Bachelor of Software Engineering Specific Degree Requirements

Chemical Engineering

In a world where population growth, economic development, and increased demands for energy, food, and healthcare all exert increasing pressures on natural resources, common development needs have to be met in a sustainable manner, without compromising the functioning of ecosystems. No single discipline is better poised to confront these third-millennium challenges than chemical engineering. Chemical engineers apply scientific and engineering principles to develop processes or systems for the economic production and distribution of useful and value-added materials through the physical, chemical, or biochemical transformation of matter. This must be accomplished with attention paid to economics, health and safety, and environmental impact.

Chemical engineers combine a sound background in the fundamental understanding of science and mathematics with highly-developed problem-solving skills to improve existing processes or methods, or to implement new ones. Chemical engineers are distinguished from physical scientists, such as chemists, by their training in the "engineering method": the use of heuristics to cause the best change in a poorly understood situation, within the available resources.

Chemical engineers design, analyze, optimize, and control processing operations, or guide others who perform these functions, in industry, government, universities, or private practice. Most materials encountered in daily life have been impacted by chemical engineering at some stage. Chemical engineers will continue to be in demand as chemical engineering evolves from its origins in the petrochemical and nuclear industries, to its current wide range of application in industries such as fine chemicals, pharmaceuticals, advanced materials and manufacturing, alternative energy, software, and cybernetics.

Current and future activity areas include:

  • Energy: conservation; renewable and non-renewable resources; fuel cells and batteries; hydrogen economy.
  • Materials: petrochemicals; biochemicals and foods; nanomaterials; consumer goods; pulp and paper; plastics and polymers; pharmaceuticals; etc.
  • Environment: pollution prevention; pollution control; climate change mitigation; recycling; environmental safety and regulations; etc.

In a world faced with growing shortages of non-renewable resources and a finite amount of renewable resources, persons wishing to use their talents to optimize the recovery or utilization of matter and energy will find chemical engineering a challenging and satisfying career, one which will place them in enviable positions with respect to the availability of employment opportunities. In addition to technical positions, chemical engineers often move into managerial functions within their companies. Traditionally, significant numbers of women enter chemical engineering and this trend continues.

Offering students a first-rate opportunity to obtain a sound, relevant background in chemical engineering, the Department of Chemical Engineering at the University of Waterloo is one of the largest and most active departments in North America. Full-time faculty, each of whom specializes in a particular sub-field through research and consulting activities, bring depth as well as breadth to the instruction and professional development of students.

Chemical Engineering at Waterloo is a co-operative education program and offers many advantages:

  • an opportunity through work terms to gain exposure to a variety of job-related experiences within chemical engineering 
  • work term salaries effectively reduce the costs associated with university education 
  • Waterloo graduates receive favourable recognition from employers for their work term experiences 
  • work terms can offer an opportunity to travel through a worldwide network of co-op employers 
  • academic terms become more meaningful and relevant against a background of work term related experience

Chemical Engineering Curriculum

The curriculum offers courses in life science and material science to provide the fundamentals required for future careers in biotechnology or nanotechnology. There are four technical elective courses that can be taken to gain depth in different areas of application of chemical engineering.

The main emphasis in the first and second year is on courses in science and mathematics which provide the foundations upon which engineering skills can be built. The upper-year core and elective courses assume and require this background.

Engineering is both a quantitative and an applied discipline, which requires a strong mathematical ability. Courses in calculus, algebra, engineering computation, differential equations, engineering economics, and statistics help develop this ability. More specialized engineering mathematics courses extend into the third year.

To perform successfully, the chemical engineer must be able to design, analyze, and control processes to produce useful and desirable products from less valuable raw materials in an efficient, economic, and socially responsible way. The knowledge and skills essential for achieving these goals are developed in the core Chemical Engineering courses taken mainly in the third and fourth years (e.g., in fluid mechanics, heat and mass transfer, thermodynamics, reactor design, biotechnology, process control, process and equipment design). Most of these courses are a mixture of theory and practice. Computer simulations and hands-on laboratory experiences are used in several courses to reinforce the theoretical principles.

Students in the fourth year complete a group project in direct collaboration with one of their professors. These projects allow students to focus on topics and industries of special interest for their career goals. Numerous Canadian companies also sponsor projects, reinforcing the bridge between academic and work term experience. There are opportunities to compete in national and international design competitions.

In the third and fourth years, students select technical elective courses to further develop their understanding of, and ability to use, engineering principles applied to important Canadian industrial sectors. Courses from other departments in the Faculty of Engineering and the University are available as electives.

An important component of the development of a professional engineer, which receives emphasis throughout the entire four-year curriculum, is frequent practice in learning to communicate technical results clearly, accurately, and effectively to others. Written practice is provided in the requirement for co-op work-term reports, which are graded by faculty members. Written and oral report requirements in laboratory and other courses provide additional practice opportunities.

Accelerated Master's Program in Chemical Engineering

Provision is made for outstanding students to pursue an Accelerated Master's program. This program provides a quicker route to the Master of Applied Science (MASc) degree. Admission is normally granted to qualified students possessing a consistently good cumulative academic record at the end of the 3A term. See Accelerated Master's Programs in Engineering for more details.

Complementary Studies Electives (CSEs)

A total of five Complementary Studies Electives (CSEs), not including MSCI 261, must be taken. The first of these courses must satisfy the Communication Skills Milestone (see below). If some Complementary Studies Electives are satisfied online or from other institutions on a Letter of Permission, when not in an academic term, each term's minimum course load must be maintained by substituting an approved "free" elective (technical or non-technical).

Communication Skills Milestone

Strong communication skills are essential to academic, professional, and personal success. To achieve the Communication Skills Milestone, Chemical Engineering students must successfully complete a foundational course on communication. This course must be taken as the first Complementary Studies Elective course (CSE in the 1B term) and selected from the following list:

Failure to achieve the Communication Skills Milestone before the end of the 2A term will result in a term decision of May Not Proceed (MNP). Communication skills are further developed and evaluated through work-term reports, as well as through design-focused (CHE 180, CHE 181, CHE 383, CHE 482, CHE 483) and investigation-focused courses (CHE 390, CHE 490, CHE 491).

Work-term Reports and Reflection Milestone

Reflection is an integral part of work-integrated learning. To achieve the Work-term Reflection Milestone, Chemical Engineering students must complete a minimum of four reflective work-term reports, one associated with each work term. These are short, structured reports offering the opportunity to reflect on practical experience obtained in the context of their academic learning and the experience requirements for professional licensure.

Students are expected to continue to develop technical communication skills in the workplace. To facilitate this, students must take PD 11 Processes for Technical Report Writing as one of their PD electives, and also complete CHE 450 Technical Work-term Report.

Ethics and Equity Milestone

This degree milestone must be met by all graduating Chemical Engineering students by either completing one course from the following list (can be taken as a CSE):

or by completing PD 22 Professionalism and Ethics in Engineering Practice.

Options, Minors, and Specializations

A number of Faculty Options, Specializations and Electives for Engineering Students are listed and described in the Engineering section. Students who satisfy the option requirements (usually seven or eight courses) will have the appropriate designation shown on their transcript.

Minors are sequences of courses, usually totaling eight to 10, which are arranged in conjunction with another academic unit outside of Engineering, such as Economics, Biology, Psychology, etc. Approval from both Chemical Engineering and the other department is required.

Usually students must take extra courses to complete a minor or a designated option. Students in Chemical Engineering are most frequently interested in the Artificial Intelligence Option, the Biomechanics Option, the Entrepreneurship Option, the Environmental Engineering Option, the Life Sciences Option, the Management Sciences Option, and the Statistics Option.

The Faculty of Engineering recognizes three designated specializations within the BASc degree in Chemical Engineering: Energy and Environmental Systems and Processes Specialization, Materials and Manufacturing Processes Specialization, and Chemical Process Modelling, Optimization and Control Specialization. These specializations are described in more detail below. Students interested in pursuing one of these specializations must take four required technical elective courses from the corresponding list of approved technical electives (List 1, List 2, or List 3). An average of at least 60% in the four specialization courses and a grade of at least 50% in each of the four courses is required. Students who satisfy the requirements for Faculty Options, Specializations and Electives for Engineering Students will have the appropriate designation shown on their diploma and transcript.

  1. The Energy and Environmental Systems and Processes Specialization (List 1) provides students with an opportunity to examine in-depth systems and processes related to energy sources, conversion, and management or the assessment and control of impacts to the environment resulting from industrial activity, depending on the exact combination of courses selected. Students interested in the design of energy or pollution control systems may be particularly interested in this specialization.
  2. The Materials and Manufacturing Processes Specialization (List 2) provides students with an opportunity to examine in-depth the properties, methods of production and processing of a broad spectrum of technologically relevant materials including polymers, metals, alloys, ceramics, composites, as well as materials of biological origin, finding application in the medical, pharmaceutical, and food industries. Focus on a specific class of materials depends on the exact combination of courses selected. Students interested in the production or processing of engineering materials may be particularly interested in this specialization.
  3. The Chemical Process Modelling, Optimization and Control Specialization (List 3) provides students with an opportunity to examine in-depth mathematical and computational approaches underpinning the simulation, optimization, and control of processes related to the production of energy and materials. Students interested in process simulation and/or optimization, in addition to control of chemical processes, may be particularly interested in this specialization.

Legend for the Next Table:


Code Description
LAB Laboratory and number of hours
LEC Lecture and number of hours
PRJ Project and number of hours
SEM Seminar and number of hours
STU
Studio and number of hours
TUT Tutorial and number of hours
A,B,C,D  These courses count toward Complementary Studies Requirements:
A- Impact, B- Engineering Economics, C- Humanities and Social Sciences, D- Other
4 Indicates Stream 4D 
8 Indicates Stream 8D 
*   20 hours4, 15 hours8 
**  12 hours4, 17 hours8
‡  Alternate weeks 
+ Laboratory, tutorial, and project component for these electives will vary

Academic Curriculum

The following curriculum is applicable to students entering Chemical Engineering in the fall 2019 term and beyond. Students admitted prior to 2019 should consult the Calendar pertinent to their year of admission for the applicable requirements. Note that CHE 425 must be completed in addition to a total of five approved Complementary Studies Electives (CSE) (excluding Engineering Economics) and four approved Technical Electives (TE).

Term Course Title and Notes

1A Fall4,8

CHE 100 Chemical Engineering Concepts 1 (3 LEC,2 TUT*)
CHE 102  Chemistry for Engineers (3 LEC,2 TUT) 
CHE 120
Computer Literacy and Programming for Chemical Engineers (2 LEC,2 LAB)
CHE 180 Chemical Engineering Design Studio 1 (1 LEC,2 STU,1 SEM)
MATH 115  Linear Algebra for Engineering (3 LEC,2 TUT) 
MATH 116  Calculus 1 for Engineering (3 LEC,2 TUT)

1B Winter8 and Spring4

CHE 101 Chemical Engineering Concepts 2 (3 LEC,2 TUT**,2 LAB)
CHE 161 Engineering Biology (3 LEC,1 TUT) 
CHE 181 Chemical Engineering Design Studio 2 (2 LEC,2 STU,1 SEM)
MATH 118  Calculus 2 for Engineering (3 LEC,2 TUT) 
PHYS 115 Mechanics (3 LEC,2 TUT)
CSE   Communication Skills Milestone (3 LEC+

2A Fall8 and Winter4

CHE 200 Equilibrium Stage Operations (3 LEC,1 TUT)
CHE 220  Process Data Analysis (3 LEC,1 TUT) 
CHE 230  Physical Chemistry 1 (3 LEC,1 TUT) 
CHE 290  Chemical Engineering Lab 1 (3 LAB) 
CHEM 262  Organic Chemistry for Engineering (3 LEC,1 TUT) 
CHEM 262L  Organic Chemistry Laboratory for Engineering Students (3 LAB) 
MATH 217  Calculus 3 for Chemical Engineering (3 LEC,1 TUT) 
CHE 298 Directed Research Project (6 PRJ) (optional extra)

2B Spring8 and Fall4

CHE 211 Fluid Mechanics (3 LEC,1 TUT)
CHE 231  Physical Chemistry 2 (3 LEC,1 TUT) 
CHE 241  Materials Science and Engineering (3 LEC,1 TUT) 
CHE 291  Chemical Engineering Lab 2 (3 LAB) 
MATH 218  Differential Equations for Engineers (3 LEC,1 TUT) 
MSCI 261  Engineering Economics: Financial Management for Engineers (3 LEC,1 TUT) 
CHE 299 Directed Research Project (6 PRJ) (optional extra)

3A Winter8 and Spring4

CHE 312 Mathematics of Heat and Mass Transfer (3 LEC,1 TUT)
CHE 314  Chemical Reaction Engineering (3 LEC,1 TUT) 
CHE 322  Numerical Methods for Process Analysis and Design (3 LEC,1 TUT) 
CHE 330  Chemical Engineering Thermodynamics (3 LEC,1 TUT) 
CHE 390  Chemical Engineering Lab 3 (3 LAB) 
CSE   Approved Complementary Studies Elective (3 LEC+
CHE 398 Directed Research Project (6 PRJ) (optional extra)

3B Fall4 and Winter8

CHE 313  Applications of Heat and Mass Transfer (3 LEC,1 TUT) 
CHE 331  Electrochemical Engineering (3 LEC,1 TUT) 
CHE 341 Introduction to Process Control (3 LEC,1 TUT)
CHE 361  Bioprocess Engineering (3 LEC,1 TUT)
CHE 383
Chemical Engineering Design Workshop (2 LEC)
TE  or
CSE or CHE 4254,8 
Approved Technical or Complementary Studies Elective (3 LEC+) or Strategies for Process Improvement and Product Development (3 LEC,1 TUT)
CHE 4508
Technical Work-term Report
CHE 399 Directed Research Project (6 PRJ) (optional extra)

4A Fall4,8

CHE 480  Process Analysis and Design (3 LEC,2 TUT) 
CHE 482  Group Design Project (1 SEM,9 PRJ) [Note: new title effective fall 2021]
CHE 490 Chemical Engineering Lab 4 (4 LAB) [Note: new title, and weight change to 0.50 effective fall 2021]
TE  or
CSE or CHE 4254 
Approved Technical or Complementary Studies Elective (3 LEC+) or Strategies for Process Improvement and Product Development (3 LEC,1 TUT) 
TE or CSE Approved Technical or Complementary Studies Elective (3 LEC+
TE or CSE
Approved Technical or Complementary Studies Elective (3 LEC+)
CHE 4504
Technical Work-term Report
CHE 498 Directed Research Project (6 PRJ) (optional extra)

4B Winter4,8

CHE 483 Group Design Project and Symposium (1 SEM,9 PRJ) [Note: new title effective winter 2022]
CHE 491
Chemical Engineering Lab 5 (4 LAB)
TE or CSE   Approved Technical or Complementary Studies Elective (3 LEC+
TE or CSE Approved Technical or Complementary Studies Elective (3 LEC+
TE or CSE   Approved Technical or Complementary Studies Elective (3 LEC+
TE or CSE or CHE 4254,8  Approved Technical or Complementary Studies Elective (3 LEC+) or Strategies for Process Improvement and Product Development (3 LEC,1 TUT)

Approved Technical Electives

Technical Elective (TE) courses for Chemical Engineering students are organized in three main thematic areas and may be selected from the following lists. Only one non-CHE course is permitted if CHE 499 is chosen. Otherwise, students may select up to two non-CHE TE courses. Courses from other departments (i.e., non-CHE) will likely require permission of the instructor and/or other prerequisites. Consult this Calendar for prerequisites and terms of offering. In brackets are recommended minimum levels that CHE students should be enrolled in before attempting a given course. Variations from this course selection list must be approved by the Department.

List 1 - Energy and Environmental Systems and Processes

Course Title and Notes
CHE 499 Elective Research Project (3B)
CHE 500 Special Topics in Chemical Engineering (contact Department)
CHE 514 Fundamentals of Petroleum Production (3B)
CHE 516 Energy Systems Engineering (3B)
CHE 571 Industrial Ecology (3B)
CHE 572 Air Pollution Control (3B)
CHE 574 Industrial Wastewater Pollution Control (3B)
EARTH 458 Physical Hydrogeology (4A)
EARTH 459 Chemical Hydrogeology (4B) 
ENVE 376 Biological Processes (3B)
ENVE 573 Contaminant Transport (4B)
ENVE 577 Engineering for Solid Waste Management (4B)
ME 452 Energy Transfer in Buildings (4B)
ME 459 Energy Conversion (3B)
ME 571 Air Pollution (4B)

List 2 - Materials and Manufacturing Processes

Course Title and Notes
CHE 499 Elective Research Project (3B)
CHE 500 Special Topics in Chemical Engineering (contact Department)
CHE 541 Introduction to Polymer Science and Properties (3B)
CHE 543 Polymer Production: Polymer Reaction Engineering (4B)
CHE 562 Advanced Bioprocess Engineering (4B)
CHE 564 Food Process Engineering (4B)
CHE 571 Industrial Ecology (3B)
ME 435 Industrial Metallurgy (4A)
ME 531 Physical Metallurgy Applied to Manufacturing (4B)
ME 533 Non-metallic and Composite Materials (4B)
MSCI 432
Production and Service Operations Management (3B)
MSCI 551 Quality Management and Control (3B)
NE 352 Surfaces and Interfaces (4A)
NE 481 Nanomedicine and Nanobiotechnology (4A)

List 3 - Chemical Process Modelling, Optimization, and Control

Course Title and Notes
CHE 499 Elective Research Project (3B)
CHE 500 Special Topics in Chemical Engineering (contact Department)
CHE 522 Advanced Process Dynamics and Control (4B)
CHE 524 Process Control Laboratory (4B)
EARTH 456 Numerical Methods in Hydrogeology (4A)
ME 362 Fluid Mechanics 2 (3B)
ME 559 Finite Element Methods (3B)
ME 566 Computational Fluid Dynamics for Engineering Design (4A)
MSCI 331 Introduction to Optimization (3B)
MSCI 332 Deterministic Optimization Models and Methods (3B) 
MSCI 431 Stochastic Models and Methods (4B) 
MSCI 432 Production and Service Operations Management (3B)
MSCI 551 Quality Management and Control (3B)
NE 451 Simulation Methods (4A)
SYDE 531 Design Optimization Under Probabilistic Uncertainty (4B) 

All undergraduate course descriptions including Chemical Engineering can be found in the Course Descriptions section of this Calendar.

 


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