Energy Engineering

Energy Engineering Doctoral Programs

  • Doctor of Engineering (D.Eng.) 
    • Energy Engineering Option  
  • Doctor of Philosophy (Ph.D.) 
    • Energy Engineering Option  

The objective of UMass Lowell's doctoral program in energy engineering is to prepare engineers for leadership positions in industry, academia, and government to provide society with sustainable energy systems.  Presently there are two areas of concentration: renewable (solar) and nuclear.  The renewable (solar) concentration is administered by the Mechanical Engineering Department and the nuclear  engineering concentration is administered by the Chemical Engineering Department. 

Admission Requirements

The applicant is required to have an M.S. degree in engineering or other suitable technical area, or its equivalent, or to have completed fifteen credit hours of graduate study, with a minimum grade point average of 3.25. 

Students may be required to make up prerequisites which they lack in comparison to the equivalent Engineering curriculum at the University of Massachusetts Lowell. In cases where a student has an M.B.A. or has completed the Business Administration Minor for Engineering students, in addition to a B.S. in engineering or its equivalent, portions or all of the management/non-technical component of the Doctor of Engineering program may be waived upon review by the administering Department. Students may apply for transfer of up to a maximum of 24 credits in acceptable graduate engineering courses (with grade of B or better) towards the doctoral program, upon approval by the Program Doctoral Committee.

Course Requirements

A total of 63 credit hours of graduate level courses are required for both the Ph.D. and D.Eng. degrees.  These credits are composed of the following components:

  • The Ph.D. degree must involve a traditional research-based dissertation, plus:   
    • A minimum of 30 approved credit hours of graduate-level engineering including associated science and math courses.
    • A minimum of 21 credit hours of doctoral dissertation.
    • The balance of the remaining 12 credits can be a mix of graduate-level engineering including associated science and math course and dissertation credits at the discretion of the department, faculty advisor and dissertation committee. 
  • The D.Eng. degree must involve a dissertation, which can be either a traditional research-based dissertation or an industry-based project, plus: 
    • 33 approved credit hours of graduate-level engineering including associated science and math courses.
    • 21 credit hours of doctoral dissertation.
    • 9 credit hours of approved management-type courses.
  • In addition to this 63 semester hours of approved graduate courses and dissertation:
    • The student must have a minimum grade point average of 3.25 to graduate. 
    • The student is required to take and pass the doctoral qualifying examination. 

Dissertations which are industrial in orientation should use the D.Eng. degree, based upon discussion with the supervising faculty advisor.  Students may elect either degree designation with the consent of the faculty advisor, subject to the requirements of each degree.

Core Courses

The core requirements will consist of two courses in advanced mathematics, two courses in thermal/fluid processes, one course in materials, and one course in systems/controls.  The specific courses follow: 

Advanced Mathematics (select two of these or suitable alternatives with approval of the graduate coordinator):

10/24.509 Systems Dynamics
10/24.539 Mathematical Methods for Engineers
92.584 Stochastic Process 
92.530 Applied Math 

Thermal/Fluid Processes (select two of these or suitable alternatives with approval of the graduate coordinator):

10.510 Advanced Separation Processes
10.520 Advanced Thermodynamics
10.528 Advanced Transport Phenomena
22.526 Transfer Processes in Energy Engineering  
22.581 Advanced Fluid Mechanics 
22.589 Finite element in Thermo-Fluids
22.513 Finite Element Methods

Materials (select one of these or a suitable alternative with approval of the graduate coordinator):

10.506 Interfacial Science and Engineering and Colloids
10.508 Material Science and Engineering
10.523 Nanodevices and Electronic Materials
26.547 Materials for Renewable Energy and Sustainability
10.535 Principles of Cell and Microbe Cultivation
95.539 Electro_Optics

Systems/Controls (select one of these or a suitable alternative with approval of the graduate coordinator):

16.513 Control Systems
16.584 Probability and Random Processes
22.575 Industrial Design of Experiments
22.554 Dynamic Systems and Control

Concentration Courses

A total of 12 credits of concentration courses must be taken, either from the renewable area or from the nuclear area. The specific courses in those areas follow:

Renewable (select four of these or suitable alternatives with approval of the graduate coordinator):

22.521 Solar Engineering Fundamentals
22.527 Solar Systems Engineering
22.504 Energy Systems Design Workshop
16.515 Power Electronics
16.528 Alternative Energy Systems
22.525 Gird-connected Solar Electric systems
22.574 design for Reliability Engineering
22.528 PV Manufacturing
22.558 Aero/Wind Engineering
95.577 Solid State Electronic and Optoelectronic Devices

Nuclear (select five of these or suitable alternatives with approval of the graduate coordinator):

24.504 Energy Engineering Workshop
24.505 Nuclear Reactor Physics
24.506 Special Topics in Nuclear Reactor Physics
24.507 Nuclear Reactor Engineering and Safety Analysis
24.508 Special Topics in Nuclear Reactor Engineering
24.511 Advanced Reactor Concepts
24.514 Hazardous and Nuclear Waste Management
24.519 Nuclear Reactor Operator Training I
24.520 Nuclear Reactor Operator Training II

Qualifying Examination

Students are required to take the qualifying examination within their first year of residency in the program.  The first part of the exam is intended to cover knowledge of undergraduate engineering and is satisfied by passing the Professional Engineering Fundamentals Exam.  The second part is intended to cover topics in an area of energy engineering of the student's interest, with the approval of the student's thesis advisor.  The written part of this examination is closed book and composed of two sections, each of three hours duration. The examination is set and evaluated by the program Graduate Examination Committee, which determines whether or not a student shall be eligible to take the oral portion. Students who pass the written part of the qualifying examination must take the oral part of the examination within 6 weeks of notification of results of the written exam.  The student is permitted two attempts at passing the qualifying examination which is administered on a declared schedule.  Students who fail the qualifying examination the first time must retake the exam at its next scheduled offering.  Students failing the doctoral exam twice will be automatically dismissed from the doctoral program. 

Dissertation

Students may register for no more than six credit hours of research in preparing a formal dissertation proposal. This proposal, and the student's ability to perform the research, must be orally defended before the student's doctoral committee and other interested parties. The written proposal and oral defense constitute the candidacy examination. Upon passing this examination and completing all course requirements, the student becomes a candidate for the D.Eng./Ph.D. degree and may register for additional research credit with the advisor's approval. 

The research work for the dissertation shall be conducted under the supervision of a program faculty advisor and a committee of two others, at least one of whom must be a faculty member in the university with the appropriate background for the thesis topic.  

Other Requirements

  • The student is required to be in full time residency at the University for at least one year. 
  • The student must have a minimum grade point average of 3.25 in order to graduate.