Bulletin Archive
This archived information is dated to the 2008-09 academic year only and may no longer be current.
For currently applicable policies and information, see the current Stanford Bulletin.
This archived information is dated to the 2008-09 academic year only and may no longer be current.
For currently applicable policies and information, see the current Stanford Bulletin.
The four-year program leading to the B.S. degree provides a foundation for careers in many facets of the energy industry. The curriculum includes basic science and engineering courses that provide sufficient depth for a wide spectrum of careers in the energy and environmental industries.
One of the goals of the program is to provide experience integrating the skills developed in individual courses to address a significant design problem. In ENERGY 199, taken in the senior year, student teams identify and propose technical solutions for a real energy-resource related problem of current interest.
The requirements for the B.S. degree in Energy Resources Engineering are similar to those described in the "School of Engineering" section of this bulletin. Students must satisfy the University general education, writing, and language requirements. The normal Energy Resources Engineering undergraduate program automatically satisfies the University General Education Requirements (GERs) in the Disciplinary Breadth areas of Natural Sciences, Engineering and Applied Sciences, and Mathematics. Engineering fundamentals courses and Energy Resources Engineering depth and elective courses must be taken for a letter grade.
The Energy Resources Engineering undergraduate curriculum is designed to prepare students for participation in the energy industry or for graduate studies, while providing requisite skills to evolve as the energy landscape shifts over the next half century. The program provides a background in mathematics, basic sciences, and engineering fundamentals such as multiphase fluid flow in the subsurface. In addition, the curriculum is structured with flexibility that allows students to explore energy topics of particular individual interest.
In brief, the unit and subject requirements are:
Subject |
Minimum Units |
Energy Resources Core |
18 |
Energy Resources Depth |
18 |
Mathematics |
25 |
Engineering Fundamentals and Depth |
24 |
Science |
30 |
Technology in Society |
3-5 |
University Requirements: IHUM, GERs, Writing, Language |
60-67 |
Total |
178-187 |
The following courses constitute the normal program leading to a B.S. in Energy Resources Engineering. The program may be modified to meet a particular student's needs and interests with the adviser's prior approval.
REQUIRED CORE IN ENERGY RESOURCES ENGINEERING
The following courses constitute the core program in Energy Resources Engineering:
ENERGY 101. Energy Resources and the Environment |
3 |
ENERGY 104. Technology in the Greenhouse: Options for Reducing Greenhouse Gas Emissions |
3 |
ENERGY 120. Fundamentals of Petroleum Engineering |
3 |
ENERGY 161. Statistical Methods for the Earth and Environmental Sciences |
3-4 |
ENERGY 175. Well Test Analysis |
3 |
ENERGY 199. Senior Project and Seminar in Energy Resources (WIM) |
4 |
Total |
19-20 |
Mathematics:
MATH 41. Single Variable Calculus
and MATH 42. Single Variable Calculus
or MATH 19. Calculus
and MATH 20. Calculus
and MATH 21. Calculus
MATH 51. Linear Algebra and Differential Calculus of Several Variables
MATH 52. Integral Calculus of Several Variables
MATH 53. Ordinary Differential Equations with Linear Algebra
or CME 102. Ordinary Differential Equations for Engineers
Science:
CHEM 31A. Chemical Principles
CHEM 31B. Chemical Principles II
or CHEM 31X may be substituted for CHEM 31A,B
CHEM 33. Structure and Reactivity
GES 1. Fundamentals of Geology
PHYSICS 41. Mechanics
PHYSICS 43. Electricity and Magnetism
PHYSICS 45. Light and Heat
PHYSICS 46. Light and Heat Laboratory
Engineering fundamentals:
CS 106A. Programming Methodology
CS 106B. Programming Abstractions
or CS 106X may be substituted for CS 106A,B
ENGR 14. Applied Mechanics: Statics
ENGR 30. Engineering Thermodynamics
ENGR 60. Engineering Economy
ME 70. Introductory Fluids Engineering
Technology in Society, 1 course
EARTH AND ENERGY DEPTH CONCENTRATION
Choose courses from the list below for a total of at least 18 units. At least one course must be completed in each category. Courses must be planned in consultation with the student's academic adviser. Appropriate substitutions are allowed with the consent of the adviser.
Fluid Flow and the Subsurface
ENERGY 121. Fundamentals of Multiphase Flow |
3 |
ENERGY 130. Well Log Analysis |
3 |
ENERGY 160. Groundwater Pollution and Oil Spills |
3 |
ENERGY 175. Well Test Analysis |
3 |
ENERGY 180. Production Engineering |
3 |
ENGR 62. Introduction to Optimization |
4 |
3D Modeling of Subsurface Structures
ENERGY 141. Practice of 3D Subsurface Modeling |
3 |
ENERGY 146. Reservoir Characterization |
3 |
GEOPHYS 112. Exploring the Geosciences with Matlab |
3 |
GEOPHYS 182. Reflection Seismology |
3 |
GES 151. Sedimentary Geology |
3 |
Earth and Energy Systems
ENERGY 102. Renewable Energy Resources |
3 |
ENERGY 153. Carbon Capture and Sequestration |
3 |
ENERGY 169. Geothermal Reservoir Engineering |
3 |
ENERGY 301. The Energy Seminar |
1 |
CEE 64. Air Pollution |
3 |
CEE 70. Environmental Science and Technology |
3 |
CEE 173B. The Coming Energy Revolution |
3 |
CEE 176B. Electric Power |
3-4 |
GEOPHYS 104. The Water Course |
3 |
A limited number of majors may be admitted to the honors program at the beginning of their senior year.
To be admitted, the student must have a grade point average (GPA) of at least 3.0 in all course work in the University. In addition to the minimum requirements for the B.S. degree, the student must complete 6 units of advanced energy resources engineering courses and at least 3 units of research (ENERGY 193).
Students who wish to be admitted to the honors program should consult with their adviser before the start of their senior year. Those who do not meet all of the formal requirements may petition the department for admission. Those completing the program receive the B.S. degree in Energy Resources Engineering with honors. An overall 3.5 GPA is required in all energy resources engineering courses for graduation with honors.
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