Undergraduate Course Catalog 2012-2013
College of Engineering and Physical Sciences
» http://www.ceps.unh.edu
Environmental Engineering (ENE)
» http://www.unh.edu/environmental-engineering/
» Click to view course offerings
Professor: Dale P. Barkey, Russell T. Carr, M. Robin Collins, Ihab H. Farag, Kevin H. Gardner, Jennifer M. Jacobs, Nancy E. Kinner, James P. Malley Jr. , Palligarnai T. Vasudevan
Associate Professor: Thomas P. Ballestero, Nivedita R. Gupta
Assistant Professor: Jillian Goldfarb
Research Assistant Professor: Robert M. Roseen, Alison W. Watts
The College of Engineering and Physical Sciences offers a bachelor of science degree in environmental engineering (ENE) and an interdisciplinary minor in environmental engineering.
The Environmental Engineering program is accredited by the Engineering Accreditation Commission of ABET, 111 Market Place, Suite 1050, Baltimore, MD 21202-4012, (410) 347-7700, http://www.abet.org
Mission
The environmental engineering program offers an undergraduate degree in environmental engineering that prepares students for productive careers in the public and private sectors and for graduate studies. The program emphasizes fundamental principles in environmental engineering and design, built upon a strong base of chemistry, physics, mathematics, and engineering science. The program prepares students to work in multidisciplinary teams that analyze, formulate, and communicate sustainable solutions to complex environmental problems. The importance of developing sustainable solutions that provide economic, social, and environmental benefits to society is emphasized. The program instills in its students an appreciation for the responsibilities engineers have to society and teaches them the skills necessary to continue learning and improving their professional expertise throughout their careers.
The ENE degree program provides an opportunity for students to specialize in industrial or municipal processes. The curriculum prepares students to plan and design systems to minimize the impact of human activity on the environment and protect human health.
Educational Objectives
ENE program graduates will have the skills, experience, and knowledge to pursue successful careers as environmental engineers. They also will have demonstrated the ability to identify information needs; locate information resources and/or design laboratory or field experiments to attain required information; and evaluate and synthesize data with sound engineering principles, methodologies, and the latest technology into creative, sustainable, safe, and economical engineering solutions to environmental engineering problems. The solutions they develop will minimize the impact of human activities on the environment and protect human health. Program graduates will have a foundation for advanced studies in environmental engineering and oral and written communication skills that will enable them to clearly explain engineering options and recommend solutions to stakeholders. ENE program graduates will have demonstrated in-depth knowledge within environmental engineering and an awareness of potential social, economic, political, and environmental impacts of engineering practices. They will have an appreciation for the contribution of environmental engineers to the benefit of society and the responsibilities of a professional environmental engineer. They will work as part of multidisciplinary teams to arrive at solutions to environmental engineering problems. ENE program graduates will be prepared to obtain professional engineering licensure; have the capacity to continue learning and improving their professional expertise and skills by participating in professional associations, conferences, workshops and courses; and understand the importance of continued professional development.
At the end of the sophomore year, students are required to have a minimum overall grade-point average of 2.0 and a grade-point average of 2.0 in all mathematics, physics, chemistry, and engineering courses to be permitted to enroll in junior-level courses. To qualify for graduation, an ENE major must: have satisfied the previously specified course requirements, have satisfied the University’s Academic Requirements, have a minimum cumulative grade-point average of 2.0, and have a minimum grade-point average of 2.0 in engineering courses.
Bachelor of Science in Environmental Engineering-Industrial Processes (IP) Emphasis
The industrial processes (IP) emphasis of environmental engineering is a process-based program that draws on the principles of chemistry, physics, mathematics, and engineering sciences. Due to the complex nature of many aspects of environmental pollution, a broad understanding of the fundamentals of engineering and sciences forms the most desirable preparation for a career in the environmental field. The program is designed to provide training not only for end-of-pipe pollution control technologies, but also for expertise in process engineering and process design, essential for achieving the objectives of pollution curtailment and prevention. Such training is especially valuable in resolving industrial pollution problems. Career opportunities for environmental engineers with this background are found in industry, research institutes, government agencies, teaching, and consulting practice. Students may also enter graduate study at the M.S. or Ph.D. levels.
Engineering design is a critical aspect of the IP curriculum. In order to meet the objective of producing creative, problem-solving engineers, design concepts are introduced early in the curriculum and design experience is integrated into every engineering course. Students learn to seek optimal solutions to open-ended problems and function in design-based team projects. Design ability is finally demonstrated at the end of the capstone course (ENE 708), when self-directed teams develop a comprehensive design report for a full-scale engineering process based on a national process design competition problem.
Since 1993, the program faculty has administered a pollution prevention internship program with industries in New Hampshire, Maine, and Massachusetts, initially funded by U.S. EPA and NHDES. In the past 12 years, the program has served more than 40 facilities. Each year about 12 students have enrolled in the pollution prevention internship program, which provides hands-on industrial employment for 10 weeks during the summer assisting industry with projects in process modification, material substitution, chemical re-use, risk assessment, safety, and economic analysis. The program faculty also assisted NHDES in setting up instrumentation in the Seacoast region of New Hampshire to monitor the precursor of ozone formation.
The B.S. program requires a minimum of 128 credits for graduation and can be completed in four years. There are nine electives in the curriculum: six for the fulfillment of the University’s Discovery Program requirements and the remaining three for technical electives to be chosen from the specified elective course list. ENE-IP students do not have to take a course in the Discovery ETS category since they satisfy this requirement through a combination of courses in their ENE-IP curriculum. Due to the substantial overlap in course requirements for the environmental engineering IP and chemical engineering majors, students will be able to transfer between these two programs during the first three semesters without losing any course credits toward graduation.
Students are required to obtain a minimum 2.0 grade-point average in CHE 501-502 and in overall standing at the end of the sophomore year in order to continue in the major. Study Abroad (Exchange) ENE-IP engineering students are required to have a cumulative GPA of 3.0 or better in math, physics, chemistry, and CHE/ENE courses at the end of the semester prior to their exchange semester.
Suggested Technical Electives
| Abbreviation | Course Number | Title | Credits |
|---|---|---|---|
| CHE | 602 | Heat Transfer and Unit Operations | 3 |
| CHE | 603 | Applied Mathematics for Chemical Engineers | 4 |
| CHE | 614 | Separation Processes | 3 |
| CHE | 705 | Fossil Fuels and Renewable Energy Sources | 4 |
| CHE | 707 | Chemical Engineering Kinetics | 3 |
| CHE | 744 | Corrosion | 4 |
| CIE | 766 | Introduction to Geo-Environmental Engineering | 3 |
| ENE | 739 | Industrial Wastewater Treatment | 3 |
| ENE | 746 | Bioenvironmental Engineering Design | 4 |
| ENE | 747 | Introduction to Marine Pollution | 3 |
| ESCI | 409 | Geology and the Environment | 4 |
| ESCI | 561 | Landscape Evolution | 4 |
| ESCI | 705 | Principles of Hydrology | 4 |
| ESCI | 715 | Global Atmospheric Chemistry | 3 |
First Year
| Abbreviation | Course Number | Title | Fall | Spring |
|---|---|---|---|---|
| CHEM | 405 | General Chemistry | 4 | - |
| MATH | 425-426 | Calculus I & II | 4 | 4 |
| PHYS | 407 | General Physics I | - | 4 |
| ENGL | 401 | First-Year Writing | 4 | - |
| ENE | 400 | Environmental Engineering Lectures I | 1 | - |
| CHE | 400 | Chemical Engineering Lectures | - | 1 |
| Discovery Program Electives | 4 | 8 | ||
| Total | 17 | 17 |
1. PHYS 407 OR CHEM 405 satisfies the Discovery Physical Science (with lab) category.
2. MATH 425 satisfies the Discovery Foundation Quantitative Reasoning category.
3. ENGL 401 satisifes the Discovery Foundation Writing Skills category.
4. ENE-IP students do not have to take a course in the Discovery ETS category since they satisfy this requirement through a combination of courses in the ENE-IP curriculum.
Sophomore Year
| Abbreviation | Course Number | Title | Fall | Spring |
|---|---|---|---|---|
| CHE | 501-502 | Introduction to Chemical Engineering I & II | 3 | 3 |
| CHEM | 683-684 | Physical Chemistry I & II | 3 | 3 |
| CHEM | 685 | Physical Chemistry Lab I | 2 | - |
| MATH | 527 | Differential Equations | 4 | - |
| PHYS | 408 | General Physics II | 4 | - |
| MATH | 644 | Statistics for Engineers and Scientists | 4 | |
| Discovery Program Electives | - | 4 | ||
| Total | 16 | 14 |
CHE 502 satisfies the Discovery Inquiry requirement.
Junior Year
| Abbreviation | Course Number | Title | Fall | Spring |
|---|---|---|---|---|
| CHE | 601 | Fluid Mechanics and Unit Operations | 3 | - |
| CHE | 604 | Chemical Engineering Thermodynamics | - | 3 |
| ENE | 612 | Unit Operations Lab II | - | 3 |
| ENE | 742 | Solid and Hazardous Waste Engineering | 3 | - |
| ENE | 756 | Environmental Engineering Microbiology | 4 | |
| CHEM | 651-652A | Organic Chemistry I & II | 3 | 3 |
| CHEM | 653 | Organic Chemistry Lab I | 2 | - |
| Discovery Program Electives | 4 | - | ||
| Technical Elective (1) | 4 | |||
| Total | 15 | 17 |
- ENE 756 satisfies the Discovery Biological Sciences requirement
Senior Year
| Abbreviation | Course Number | Title | Fall | Spring |
|---|---|---|---|---|
| CHE | 703 | Mass Transfer and Stagewise Operations | 3 | - |
| ENE | 708 | Industrial Process Design | - | 4 |
| ENE | 709 | Fundamentals of Air Pollution and Control | 4 | - |
| ENE | 713 | Unit Operations Lab II | 3 | - |
| ENE | 752 | Process Dynamics and Control | - | 4 |
| ENE | 772 | Physicochemical Processes for Water/Air Quality | - | 4 |
| ESCI | 710 | Groundwater Hydrology | - | 4 |
| Technical Electives (2) | 6-8 | - | ||
| Total | 16-18 | 16 |
ENE 708 satisfies the Discovery Capstone Experience/Course.
Bachelor of Science in Environmental Engineering-Municipal Processes (MP) Emphasis
Environmental engineers graduating from the municipal processes (MP) emphasis will plan, design, and construct public and private facilities to minimize the impact of human activity on the environment and to protect human health. For example, environmental engineers with a municipal processes perspective design and build drinking water treatment systems, municipal and industrial wastewater treatment plants, solid waste management facilities, contaminated ground water remediation systems, and hazardous waste remediation facilities. These facilities must meet regulatory requirements, be cost effective to build and maintain, be safe to operate, and have minimal environmental impact.
In ENE 400 and 401, students are introduced to the full spectrum of environmental engineering projects that they will subsequently explore in design teams during their degree program. As part of these experiences, students visit and tour field sites, and interact with engineers who have been involved in the design and/or construction of the projects. Design is integrated throughout the curriculum, and particularly emphasized in junior- and senior-level courses. As part of these projects, students analyze treatment alternatives, recommend a system that meets regulatory operational needs, and prepare an implementation schedule and project budget. Detailed design projects are performed in ENE 744 and 746. ENE 788 serves as a capstone design experience where students work on a multi-interdisciplinary environmental engineering projects, and apply skills learned in other courses while working with real-world clients. ENE-MP students do not have to take a course in the Discovery Biological Science category since they satisfy this category with ENE 756 Environmental Engineering Microbiology.
The following schedule is a sample of a planned program for environmental engineering students completing the major within the municipal processes emphasis.
First Year
| Abbreviation | Course Number | Title | Fall | Spring |
|---|---|---|---|---|
| ENE | 400, 401 | Environmental Engineering Lectures I, II | 1 | 1 |
| ENGL | 401 | First-Year Writing | 4 | - |
| MATH | 425, 426 | Calculus I, II | 4 | 4 |
| Discovery Electives* | 4 | 4 | ||
| CHEM | 405 | General Chemistry | 4 | - |
| PHYS | 407 | General Physics I | - | 4 |
| ENGL | 502 | Technical Writing | 4 | |
| Total | 17 | 17 |
Second Year
| Abbreviation | Course Number | Title | Fall | Spring |
|---|---|---|---|---|
| ENE | 520 | Environmental Pollution and Protection | 4 | - |
| ENE | 521 | Environmental Engineering Seminar | - | 1 |
| CIE | 525 | Statics | 3 | - |
| MATH | 527 | Differential Equations with Linear Algebra | 4 | - |
| MATH | 644 | Statistics for Engineers and Scientists | - | 4 |
| CHEM | 545 | Organic Chemistry Lecture | 3 | - |
| CHEM | 546 | Organic Chemistry Laboratory | 2 | - |
| CIE | 533 | Project Engineering | - | 3 |
| TECH | 564 | Fundamentals of CAD | - | 3 |
| Discovery Elective* | - | 4 | ||
| Total | 16 | 15 |
Third Year
| Abbreviation | Course Number | Title | Fall | Spring |
|---|---|---|---|---|
| CIE | 642 | Fluid Mechanics | 4 | - |
| Technical Elective** | 4 | - | ||
| ENE | 645 | Fundamental Aspects of Environmental Engineering | - | 4 |
| ENE | 756 | Environmental Engineering Microbiology | - | 4 |
| ENE | 742 | Solid and Hazardous Waste Engineering | 3 | - |
| Engineering Lab Elective** | - | 4 | ||
| Hydraulics Elective** | - | 3-4 | ||
| Discovery Elective* | 4 | - | ||
| Total | 15 | 15/16 |
**Approved lists of technical, hydraulics, engineering laboratory, and ENE design and non-design electives are available from the ENE-MPundergraduate coordinator, Nancy Kinner. Students must take a minimum of three 700-level ENE electives totaling at least 10 credits. One ENE elective course must be from the design category.
Fourth Year
| Abbreviation | Course Number | Title | Fall | Spring |
|---|---|---|---|---|
| ENE | 746 | Bioenvironmental Engineering Design | 4 | - |
| Discovery Elective* | 4 | - | ||
| Environmental Engineering Elective** | 3-4 | 6-8 | ||
| ENE | 744 | Physicochemical Treatment Design | - | 4 |
| ENE | 784 | Intro to Project Planning & Design | 1 | - |
| ESCI | 710 | Groundwater Hydrology | - | 4 |
| ENE | 788 | Project Planning and Design | - | 3 |
| ENE | 749 | Water Chemistry | 4 | - |
| Total | 16/17 | 17/19 |
*See Discovery Program requirements. The Discovery requirements for Writing, Quantitative Reasoning, and Physical Science are fulfilled by ENGL 401, MATH 425, and PHYS 407, respectively. ENE 520 fulfills the Environmental, Technology, and Society requirement. ENE 784 and 788 fulfill the Senior Capstone requirement. Environmental Engineering Microbiology will fulfill Biological Science. Courses in the ENE:MP curriculum designated Discovery Electives can be selected from the University’s approved Discovery Program courses in Fine and Performing Arts, Humanities, Historical Perspectives, World Cultures, and Social Science. One of these electives must have an inquiry attribute.
The municipal processes emphasis of the ENE program requires a minimum of 128 total credits for graduation.
Environmental Engineering Minor
The environmental engineering minor is intended primarily for students in engineering and physical sciences who are not in the chemical, civil, or environmental engineering degree programs. Students contemplating such a minor should plan on a strong background in the sciences and mathematics (including differential equations).
The minor provides a comprehensive introduction to major areas of interest in environmental protection—namely, air pollution and water pollution—through the three required courses. Further breadth in environmental engineering or depth in specific areas can be attained through the choice of appropriate elective courses.
The minor requires a minimum of five courses, as follows: 1) three required courses: ENE 645, Fundamental Aspects of Environmental Engineering; ENE 709, Fundamentals of Air Pollution and Its Control; and ENE 772, Physicochemical Processes for Water and Air Quality Control, or ENE 743, Environmental Sampling and Analysis; and 2) a minimum of two elective ENE courses.
Choice of elective courses should be made in consultation with the minor area adviser, Nancy Kinner, ENE-MP, or Niva Gupta, ENE-IP. Students normally start this program in the junior year and should declare their intention to enter the program as early as possible during the sophomore year. During the final semester, students must apply to the dean to have the minor appear on the transcript.
