SUETRI-B Energy Science and Engineering Energy Science & Engineering

About SUETRI-B

Our mission is to constantly advance the state of reservoir modeling technologies, quickly transfer this knowledge to our members, train future leaders in this field, and where appropriate collaborate with member organizations on joint research.

Reservoir simulation is the art, science and engineering of modeling flow and transport processes in porous media, including oil and gas reservoirs and aquifers. It is a core competency and a primary tool for making reservoir management decisions. Reservoir simulation includes the development and implementation of efficient numerical techniques for accurate solution of the equations governing multi-component, multiphase flow in natural porous media. Reservoir simulation includes detailed modeling of wellbore flow, accurate representation of advanced wells, and integration of the reservoir model with production facilities. Reservoir simulation is also used to quantify the uncertainty associated with performance predictions. It is also expanding to include history matching and optimization of the entire system in the presence of uncertainty.

We work in virtually all aspects of reservoir simulation, and our research program is constantly evolving to meet the changing needs of the industry, the wider community, and the interests of students.  

Our current and past research includes work in the following areas:

  • Pore-scale modeling of fluid and solid mechanics
  • Thermal-compositional formulations
  • Design and implementation of general-purpose research simulators
  • Generation of flexible and unstructured grids
  • Discretization and upscaling of heterogeneous , geometrically complex models
  • Discrete fracture modeling
  • Multiscale methods for flow and transport in heterogeneous media
  • Scalable linear and nonlinear solvers
  • Accurate modeling of subsurface CO2 sequestration processes
  • Unstable miscible and immiscible flows
  • Coupled fluid flow and geomechanics
  • Modeling of multiphase flow in wellbores and production facilities
  • Accurate modeling of near wellbore flow behaviors
  • Coupled simulation of advanced wells and reservoirs
  • History matching and optimization of reservoir performance
  • Uncertainty quantification methods

Our Reservoir Simulation Research program (SUETRI-B) is dedicated not only to the research and development of techniques that enhance the value of the reservoir simulation technology, but also to the education of future leaders in this field and the broader energy industry. The SUETRI-B activities are coordinated with our Smart Fields consortium in order to minimize overlap and leverage the enormous strength of the two groups. We also benefit from other research programs within and outside the Department of Energy Science & Engineering at Stanford University. The SUETRI-B research group typically has 20-25 students, 5-7 post-doctoral fellows, and 2-3 research associates. Professors Hamdi Tchelepi, Lou Durlofsky, and Khalid Aziz co-direct the SUETRI-B program. Please review the Research Policy Handbook for more information regarding visiting scholar requirements.