Stanford University Renewable Energy Master’s

Last Updated on December 24, 2022

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Energy Degrees

Stanford’s energy programs provide an excellent opportunity for students interested in energy.  The interdisciplinary nature of these programs allow students to draw strength from all seven of Stanford’s schools and to prepare them for careers in the energy field.

Undergraduate

  • Bachelor of Science in Energy Resources Engineering
  • Bachelor of Science in Civil and Environmental Engineering (with concentration in Atmosphere/Energy)

Master’s

  • Master of Science in Energy Resources Engineering
  • Master of Science in Civil and Environmental Enginering (with concentration in Atmosphere/Energy)
  • E-IPER Joint Master of Science

PhD

  • PhD in Energy Resources Engineering
  • PhD in Civil and Environmental Engineering (with concentration in Atmosphere/Energy)
  • PhD degree specializing in environmental, energy and natural resource economics
  • E-IPER PhD in Environment and Resources

Professional Programs

  • Energy Innovation and Emerging Technologies Certificate

M.S. Program

The Energy Resources Engineering department offers two distinct degree programs at both the M.S. and Ph.D. levels.  One program leads to the degrees of M.S. or Ph.D. in Petroleum Engineering, and the other leads to the degrees of M.S. or Ph.D. in Energy Resources Engineering.  The Engineer degree, which may be offered in either Petroleum Engineering or Energy Resources Engineering, is an extended form of the M.S. degree with additional coursework and research.

Master of Science – Petroleum Engineering or Energy Resources Engineering

The objective is to prepare the student for professional work in the energy industry through completion of fundamental courses in the major field and in related sciences as well as independent research.

Students entering the graduate program are expected to have an undergraduate-level energy resources engineering background. Competence in computer programming in a high-level language (CS 106X or the equivalent) and knowledge of energy resources engineering and geological fundamentals (ENERGY 120, 130, and GES 151) are prerequisites for taking most graduate courses.

The candidate must fulfill the following requirements:

  1. Register as a graduate student for at least 45 units.
     
  2. Submit a program proposal for the Master’s degree approved by the adviser during the first quarter of enrollment.
     
  3. Complete 45 units with at least a grade point average (GPA) of 3.0. This requirement is satisfied by taking the core sequence, selecting one of the seven elective sequences, an appropriate number of additional courses from the list of technical electives, and completing 6 units of master’s level research. Students electing the course work only M.S. degree are strongly encouraged to select an additional elective sequence in place of the research requirement. Students interested in continuing for a Ph.D. are expected to choose the research option and enroll in 6 units of ENERGY 361. All courses must be taken for a letter grade.
     
  4. Students entering without an undergraduate degree in Petroleum Engineering must make up deficiencies in previous training. Not more than 10 units of such work may be counted as part of the minimum total of 45 units toward the M.S. degree. Research subjects include certain groundwater hydrology and environmental problems, energy industry management, flow of non-Newtonian fluids, geothermal energy, natural gas engineering, oil and gas recovery, pipeline transportation, production optimization, reservoir characterization and modeling, carbon sequestration, reservoir engineering, reservoir simulation, and transient well test analysis.

Energy Resources Engineering

The Department of Energy Resources Engineering (ERE) awards the following degrees: Bachelor of Science, Master of Science, Engineer, and Doctor of Philosophy in Energy Resources Engineering. The department also awards the Master of Science, Engineer, and Doctor of Philosophy degrees in Petroleum Engineering. Contact the ERE student services office to determine the relevant program.

Energy Resources Engineering contributes to the engineering science needed to maintain and diversify the energy supply while finding the most rapid pathways toward greater energy sustainability. Energy Resources Engineering is concerned with the production, transformation, and impacts of energy resources including renewables and fossil fuels. Oil and natural gas are important components of the current energy system due to their widespread use, economic importance, and contributions to climate change.  The flow of water, oil, and gas in the subsurface are important to quantify accurately for energy recovery, energy storage, environmental assessment, and carbon storage.

The program also has a strong interest in related energy topics such as renewable energy, global climate change, carbon capture and sequestration, energy storage and energy systems. The Energy Resources Engineering curriculum provides a sound background in basic sciences and their application to practical problems to address the complex and changing nature of the field. Course work includes the fundamentals of physics, chemistry, geology, computational physics, numerical analysis, and engineering science.  Applied courses cover most aspects of energy resources engineering and some related fields such as geostatistics. The curriculum includes the fundamental aspects of energy transfer and fluid flow in subsurface geologic formations, as well as the storage, transmission and utilization of energy at the surface. These principles apply to the optimization of energy recovery from hydrocarbon and geothermal reservoirs, subsurface sequestration of carbon dioxide, energy storage, and the remediation of groundwater systems.

Faculty, graduate students, and postdoctoral scholars conduct research in areas including: energy system modeling and optimization; energy storage; data assimilation and uncertainty quantification; numerical reservoir simulation; carbon sequestration; enhanced oil recovery; geostatistical reservoir characterization; geothermal engineering; production optimization; power production from wind and wave energy; and well test analysis. Undergraduates are encouraged to participate in research projects.

The department is housed in the Green Earth Sciences Building and operates laboratories for research in batteries and energy storage, enhanced oil recovery processes, geological carbon storage operations, and geothermal engineering. Students have access to a variety of computer platforms and software for research and course work.

Mission of the Undergraduate Program in Energy Resources Engineering

The mission of the Energy Resources Engineering major is to provide students with the engineering skills and foundational knowledge needed to flourish as technical leaders within the energy industry. Such skills and knowledge include resource assessment, choices among energy alternatives, and carbon management, as well as the basic scientific background and technical skills common to engineers. The curriculum is designed to prepare students for immediate participation in many aspects of the energy industry and graduate school.

Learning Outcomes (Undergraduate)

The department expects undergraduate majors in the program to be able to demonstrate the following learning outcomes. These learning outcomes are used in evaluating students and the department’s undergraduate program. Students are expected to:

  1. apply skills developed in fundamental courses to real-world engineering problems.
  2. research, analyze, and synthesize solutions to an original and contemporary energy problem.
  3. work independently and as part of a team to develop and improve engineering solutions.
  4. apply written, visual, and oral presentation skills to communicate engineering and scientific knowledge.

Graduate Programs in Energy Resources Engineering

The Energy Resources Engineering department offers two distinct degree programs at both the M.S and Ph.D. levels. One program leads to the degrees of M.S. or Ph.D. in Energy Resources Engineering, and the other leads to the degrees of M.S. or Ph.D. in Petroleum Engineering. The Engineer degree, which is offered in either Energy Resources Engineering or Petroleum Engineering, is an extended form of the M.S. degree with additional course work and research.

Learning Outcomes (Graduate)

The objective is to prepare students to be technical leaders in the energy industry, academia and research organizations through completion of independent research as well as fundamental courses in the major field and in related sciences. Students are expected to:

  1. apply skills developed in fundamental courses to engineering problems.
  2. research, analyze, and synthesize solutions to an original and contemporary energy problem.
  3. work independently and as part of a team to develop and improve engineering solutions.
  4. apply written, visual, and oral presentation skills to communicate scientific knowledge.
  5. M.S. students are expected to develop in-depth technical understanding of energy problems at an advanced level.
  6. Ph.D. students are expected to complete a scientific investigation that is significant, challenging and original.

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