Chemical engineering deals with the chemical, biological, and physical processes for converting raw materials to valuable products and with the design of such products. Students apply principles of physics, chemistry, mathematics, biology, and health and safety sciences to the analysis, design, and automatic control of these processes. The biochemical engineering option focuses on biochemical and biological processes that require the integration of biochemistry and molecular biology with the core chemical engineering curriculum and other basic sciences. Special programs are available for those who wish to pursue careers as chemical engineers in medicine or biomedical engineering, polymer process engineering and science, environmental engineering, pharmaceutical engineering, and food engineering.
The achievements of chemical and biochemical engineering constantly touch our daily lives. Past and current breakthroughs include the large-scale production of antibiotics; plastics, synthetic rubber, and polymeric fabrics; semiconduction; gasoline and aviation fuel; hydrocarbon-based chemicals from oil, coal, and renewable resources; water and air purification systems; management of hazardous wastes; fertilizers, nutritional synthetic foods, and dietary supplements; dyes, paints, and solvents; kidney dialysis machines and artificial skin; biological production of alcohol or methane gas from controlled microbial digestion of natural and industrial waste materials; and development of bioreactors using enzymes and cells to enhance production of foods, drugs, and specialty chemicals.
The broad education provided by these options and special programs allows students to choose from a wide variety of careers. Many graduates work in large corporations as well as smaller companies as practicing chemical or biochemical engineers. The degree program also prepares qualified students for graduate study leading to the master of science (M.S.) or doctor of philosophy (Ph.D.) degree in chemical and other engineering disciplines, including specialties in biomedical, environmental, polymer, food, and pharmaceutical engineering. In addition, students are prepared to meet the graduate entrance requirements for medical and law schools, business administration, and other professional disciplines.
The curriculum is designed to prepare and train students for entry into the profession equipped with the fundamental knowledge in core sciences required for problem solving and critical thinking. Graduates will have the tools needed to design and analyze complex chemical engineering systems. Training in ethical, health and safety, and societal concerns as they relate to the chemical engineering profession is also provided. Graduates further learn effective communication skills and gain valuable experience working in a team environment. The B.S. program in chemical engineering is accredited by the Engineering Accreditation Commission of ABET.
Program Educational Objectives
The program educational objectives are: (1) to provide chemical and biochemical engineering graduates with skills and tools to become innovative, competent, contributing engineers in the chemical and biochemical industries; (2) to ensure our graduates have sufficient flexibility and adaptability in the workplace so that they remain effective engineers, take on new responsibilities, move into new areas of opportunity, and assume leadership roles; and (3) to train our graduates to continue their professional development and obtain M.S. and Ph.D. degrees in engineering and allied disciplines, including business, medicine, and law.
Program Outcomes and Teaching Goals
Each curriculum within the School of Engineering is designed to ensure that its graduates have achieved: (1) an ability to apply knowledge of mathematics, science, and engineering; (2) an ability to design and conduct experiments, as well as to analyze and interpret data; (3) an ability to design a system, component, or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability; (4) an ability to function on multidisciplinary teams; (5) an ability to identify, formulate, and solve engineering problems; (6) an understanding of professional and ethical responsibility; (7) an ability to communicate effectively; (8) the broad education necessary to understand the impact of engineering solutions in a global, economic, and societal context; (9) a recognition of the need for an ability to engage in lifelong learning; (10) a knowledge of contemporary issues; and (11) an ability to use the techniques, skills, and modern engineering tools necessary for engineering practice.