Short Course Catalogue - Reservoir Characterization
Instructors: Prof. Dr Franek Hasiuk (Iowa State University) and Dr Sergey Ishutov (University of Alberta)
3D printing is an emerging tool in the geoscience research, reservoir characterization, education, and technical communication. This course covers fundamentals of available techniques and materials for 3D printing and their relative merits. Participants will learn about applications of 3D printing in studies of reservoir rocks, fossils, and geomorphology. The practical section of the course will allow participants: 1) to design 3D-printable models of reservoir rocks that contain pore and fracture networks using CAD and computed tomography data; 2) to render 3D terrain models using GIS data; and 3) to test the accuracy of digital and 3D-printed models.
Instructor: Prof. Dr Michael Poppelreiter (University Technology Petronas)
Hands-on microfacies characterization using industry data sets. Analysis: mineralogy, components, pore types, diagenesis. Participants are instructed on how to capture observations such that patterns and rules might be detected. The course encourages participants to think of processes and products during thin section characterization. Industry data sets are used to illustrate the use of microfacies characterization to help solve operational issues of carbonate fields. Production increase is demanded. Wells (fully cored) show contrary production behavior. The stratigraphy is ‘layer cake’ and both wells are perforated in the highest perm interval of a few meters thick. Thin sections are linked with petrophysical data, openhole logs and production data. Course participants are encouraged to use thin section descriptions to develop a conceptual model for permeability based on a depositional model architecture based on the investigation of available this sections.
Instructors: Dr Leon Thomsen (Delta Geophysics, United States)
Classical reservoir characterization typically assumes that the reservoir is elastically and hydraulically isotropic. However, most real reservoirs are actually anisotropic, and spatially heterogeneous (on many scales), so that core and/or log data are not representative of the larger reservoir volume. Hence, the best means to physically characterize most real reservoirs, throughout their full volume, uses seismic data, acquired and interpreted anisotropically. This course summarizes the state-of-the-art of seismic reservoir characterization, using anisotropic seismic rock physics.
* Physical principles
* Pore pressure
* Anisotropic AVO
Instructors: Dr Per Avseth (Independent Consultant) and Prof. Dr Tor Arne Johansen (University of Bergen)
The field of rock physics represents the link between qualitative geologic parameters and quantitative geophysical measurements. Increasingly over the last decade, rock physics stands out as a key technology in petroleum geophysics, as it has become an integral part of quantitative seismic interpretation. Ultimately, the application of rock physics tools can reduce exploration risk and improve reservoir forecasting in the petroleum industry.
Instructor: PhD José M. Carcione (OGS)
This course presents the fundamentals of physics and numerical simulation of wave propagation in anisotropic, anelastic and porous media, including the analogy between acoustic waves (in the general sense) and electromagnetic (EM) waves. The emphasis is on geophysical applications for hydrocarbon exploration, but researchers in the fields of earthquake seismology, rock physics, and material science. Moreover, the course illustrates the use of seismic and EM modelling, with an account of the numerical algorithms for computing the synthetic seismograms and radargrams, including applications in the field of geophysical prospecting, seismology and rock physics, such as evaluation of methane hydrate content, upscaling techniques, detection of overpressure, Antarctic and permafrost exploration, exploration of the Earths deep crust, time-lapse for monitoring of CO2 injection, etc.
Instructor: Prof. Tapan Mukerji (Stanford University)
This course covers fundamentals of Rock Physics ranging from basic laboratory and theoretical results to practical “recipes” that can be immediately applied in the field. Application of quantitative tools for understanding and predicting the effects of lithology, pore fluid types and saturation, saturation scales, stress, pore pressure and temperature, and fractures on seismic velocity. We will present case studies and strategies for quantitative seismic interpretation using statistical rock physics work flows, and suggestions for more effectively employing seismic-to-rock properties transforms in Bayesian machine learning for reservoir characterization and monitoring, with emphasis on seismic interpretation and uncertainty quantification for lithology and subsurface fluid detection.
Instructor: Dr Colin Sayers (Schlumberger)
The state of stress within the earth has a profound effect on the propagation of seismic and borehole acoustic waves, and this leads to many important applications of elastic waves for solving problems in petroleum geomechanics. The purpose of this course is to provide an overview of the sensitivity of elastic waves in the earth to the in-situ stress.
Instructor: Dr Jorg Herwanger (MP Geomechanics)
Geomechanical models consist of (i) mechanical rock properties, (ii) pore pressure and (iii) stress state. Applications of geomechanical models in reservoir development and management include assessing mudweight windows for drilling, diagnosing wellbore failure, analysing conditions for breach of seal integrity and fault re-activation, evaluating fracture containment during hydraulic stimulation, and predicting reservoir compaction and overburden subsidence.
The purpose of this course is to provide an overview of currently available techniques to build calibrated 3D and 4D geomechanical models and apply these models for field development and management applications. By attending the course, participants will deepen their insight into each of the elements that comprise geomechanical models, and give guidance how to interpret geomechanical models for a range of applications.
Instructor: Dr Dirk Nieuwland (NewTec International)
Flow of oil and gas through porous reservoir rock is controlled by the permeability of the reservoir. In the simplest case this is a single permeability system that is completely controlled by the rock properties of the reservoir. The presence of faults and/or fractures complicates the flow by creating a dual porosity/permeability system when open fractures are present, or by creating barriers to flow or even reservoir compartmentalization when sealing faults or fractures are present. In this short course the origin of faults and fractures and their mechanical properties will be discussed in a framework of geo-mechanics. Understanding the physical processes of fault and fracture formation enables the development of predictive models even in structurally complicated reservoirs. A combination of theory, case histories and exercises will be used to familiarize the participants of this short course with the subjects. The nature of a short course is such that an full in-depth treatment of the mechanics is not possible due to lack of time, the course emphasis will therefore be on informative case histories. Exercises will make part of the course but in view of the available time need to be relatively short.
Instructors: Dr David Wiprut (Baker Hughes, a GE Company - Houston, USA)
This course covers the principles of in-situ stress and rock mechanics and their applications. We introduce applications in complex wellbores, in reservoirs that are faulted, fractured, depleted, or compacting, and in unconventional reservoirs. Concepts are reinforced and engagement is ensured with 18 class exercises and many more class discussion questions. The course is composed of five sections: 1) Introduction to Geomechanics; 2) Drilling; 3) Completions Engineering; 4) Geology and Geophysics; and 5) Reservoir Engineering.
Instructor: Prof. Dr Alexei Milkov (Colorado School of Mines)
This course enables participants to add value in E&P projects through interpretation of natural gases. Examples and case studies come from conventional and unconventional petroleum systems around the world. The instructor will transfer his practical knowledge of most important and relevant theories, interpretation tools and applications used in the industry. The learning objectives are achieved through well-illustrated lectures, numerous hands-on exercises and active class discussions.
We will cover:
• Natural gas composition and properties;
• Sampling and analytical techniques;
• Hydrocarbon gases: origin and processes;
• Prediction of non-hydrocarbon gases;
• Using gas data/models to solve business problems in exploration, appraisal/development, production and environmental projects.
Instructor: Prof. Dr Alexei Milkov (Colorado School of Mines)
The course enables participants to interpret fluids and source rock data to add value to E&P projects from exploration to environmental remediation. Examples and case studies come from both conventional and unconventional petroleum systems around the world. The learning objectives are achieved through well-illustrated lectures, numerous hands-on exercises and active class discussions.
We will cover the following topics:
• Petroleum composition and properties;
• Sampling and analytical techniques;
• Characterization of source rocks, prediction of fluid properties in exploration prospects;
• Assessing reservoir compartmentalization;
• Geochemical surveillance of oil/gas production;
• Use of geochemical data to locate producing intervals and allocate petroleum production;
• Petroleum spills and leaks.