World-class training for the modern energy industry

Type: Classroom

Nuclear Technology (G512)

Tutor(s)

Brian Matthews: Independent Consultant, Founder and Managing Director of TerraUrsa.

Overview

This course covers all aspects of nuclear technology and power production.

Duration and Logistics

Classroom version: A 3-day course comprising a mix of lectures, case studies and exercises. The manual will be provided in digital format and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Virtual version: Five 3.5-hour interactive online sessions presented over 5 days. A digital manual and exercise materials will be distributed to participants before the course. Some reading and exercises are to be completed by participants off-line.

Level and Audience

Fundamental. The course is intended for people with a basic engineering or scientific background.

Objectives

You will learn to:

  1. Understand the scientific and technological background of nuclear power.
  2. Describe how a nuclear power plant/power station works.
  3. Characterize the effects and risk of radiation.
  4. Evaluate how the history of the nuclear industry has shaped policy and public engagement today.
  5. Interpret a typical nuclear fuel cycle (mining to disposal).
  6. Develop an understanding of the economics and policy surrounding nuclear power and its growth internationally.
  7. Assess the social impact of nuclear power and its benefits to climate change and achieving Net Zero.
  8. Understand the future options for nuclear technologies and how they can work alongside other technologies.

Fractures and associated Structural Concepts for the GeoEnergy Transition: a Virtual Field Course (G511)

Tutor(s)

Richard Jones: Managing Director, Geospatial Research Ltd.

Overview

Making extensive use of virtual outcrop technologies, this course will provide participants with a field trip itinerary that includes contrasting natural fracture networks from a wide range of rock types and structural settings. The course will combine fieldwork-based appraisal of fractures with collation and processing of different types of fracture data and their practical uses in GeoEnergy Transition applications.

Duration and Logistics

Classroom version: A 3-day course comprising a mix of lectures, case studies and exercises. The manual will be provided in digital format and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Virtual version: Five 3.5-hour interactive online sessions presented over 5 days. A digital manual and exercise materials will be distributed to participants before the course. Some reading and exercises are to be completed by participants off-line.

Level and Audience

Intermediate. The course is intended for geoscientists looking to understand the importance of fracture systems and to learn practical methods of appraising natural fracture networks. Target participants include geologists, geoengineers and hydrogeologists, as well as oil and gas professionals looking to apply their existing expertise in new sectors.

Objectives

You will learn to:

  1. Describe the geometry and morphology of individual fractures in outcrop, and interpret the mode of fracturing.
  2. Assess relative timing of fractures, and designate fractures to different sets.
  3. Supplement outcrop data with interpretation from aerial and satellite imagery.
  4. Characterize spatial properties of the fracture network, including spacing, clustering and scaling (size-intensity) relationships.
  5. Evaluate the nature of fracturing in relation to larger scale features: folds, faults and mechanical stratigraphy.
  6. Collate fracture data to produce a conceptual fracture model.
  7. Understand the interplay between fractures and matrix, in terms of porosity and permeability, and the implications for fluid storage and flow.
  8. Predict the general performance of a fracture network in practical GeoEnergy Transition applications.
  9. Recognize the strengths and limitations of different sources of fracture data, and the advantage of combining field data with other data types.

An Introduction to Geospatial Workflows (G510)

Tutor(s)

Richard Jones: Managing Director, Geospatial Research Ltd.

Overview

This course provides a broad overview of geoinformatics and the practical application of geospatial technologies to tackle key challenges of the GeoEnergy Transition.

Duration and Logistics

Classroom version: A 1.5-day course comprising a mix of lectures, case studies and exercises. The manual will be provided in digital format and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Virtual version: Three 3.5-hour interactive online sessions presented over 3 days. A digital manual and exercise materials will be distributed to participants before the course. Some reading and exercises are to be completed by participants off-line.

Level and Audience

Fundamental. The course is intended for any geoscientists looking to increase their understanding and practical experience of spatial data and workflows.

Objectives

You will learn to:

  1. Recognise different types of spatial data, and how they can be represented and stored in Geographic Information Systems (GIS) and related software.
  2. Describe the pros and cons of 2-D and 3-D geospatial user interfaces as a primary way to organize and access data.
  3. Understand spatial resolution, precision and accuracy.
  4. Assess different approaches to evaluating spatial data, including geostatistics and geospatial analysis.
  5. Download and process earth observation satellite imagery.
  6. Acquire and process Global Navigation Satellite System (GNSS) data for high precision spatial positioning.
  7. Evaluate current trends in the GeoEnergy Transition.

Geology and Fractures for High Enthalpy Geothermal (G507)

Tutor(s)

David McNamara: Lecturer in the Department of Earth, Ocean and Ecological Sciences, University of Liverpool.

Overview

This course covers aspects of geoscience relevant to high enthalpy geothermal systems. It will introduce the geothermal system play concept and geothermal field classification. Teaching materials and exercises will provide skill development in how to characterize important aspects of the geology of these geothermal systems from structural networks, permeability, geomechanics and more.

Duration and Logistics

Classroom version: A 3-day course comprising a mix of lectures, case studies and exercises. The manual will be provided in digital format and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Virtual version: Five 3.5-hour interactive online sessions, comprising three lecture sessions and two practical sessions (one on working with borehole image logs in geothermal wells and interpreting these datasets, and the other on stress field characterization from well data). The sessions are presented over 5 days. A digital manual and exercise materials (including well logs) will be distributed before the course. Some reading and exercises are to be completed by participants off-line.

Level and Audience

Advanced. The course is intended for all career stage industry professionals and early career researchers with a geoscience or geo-engineering background, including those with a familiarity in oil and gas production.

Objectives

You will learn to:

  1. Recognize the geological components of a geothermal system play.
  2. Understand the range of data required to characterize a fractured geothermal reservoir.
  3. Characterize fracture and stress data from a geothermal reservoir that can be used in geomechanical models and flow models.
  4. Determine potential geological controls on well permeability.

Introduction to Low Enthalpy Geothermal Exploration (G506)

Tutor(s)

Mark Ireland: Senior Lecturer in Energy Geoscience, Newcastle University.

Overview

This course covers all aspects of low enthalpy geothermal exploration and production. It is intended as an introduction to the entire lifecycle of low enthalpy geothermal resources, covering aspects of geoscience and engineering.

Duration and Logistics

Classroom version: A 3-day course comprising a mix of lectures, case studies and exercises. The manual will be provided in digital format and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Virtual version: Five 3.5-hour interactive online sessions presented over 5 days. A digital manual and exercise materials will be distributed to before the course. Some reading and exercises are to be completed by participants off-line.

Level and Audience

Intermediate. The course is intended for all career stage industry professionals and early career researchers with a geoscience or geo-engineering background, including those with a familiarity in oil and gas production.

Objectives

You will learn to:

  1. Understand the applications and use of low enthalpy geothermal energy.
  2. Recall the basic principles of heat generation within the upper crust.
  3. Describe the key characteristics of geothermal resources and reservoirs.
  4. Understand the production options for low enthalpy geothermal resources.
  5. Appreciate project risks and uncertainties in developing geothermal resources.

Subsurface Pressures for Injection of Fluids and Gases (G504)

Tutor(s)

Richard Swarbrick: Manager, Swarbrick GeoPressure.

Overview

This course covers all aspects of subsurface pressures with particular emphasis on pre-drill estimates and the conditions for injection and storage of fluids and gas, including hydrogen and CO2. Methods for estimating pressures from rock and fluid properties will be reviewed, as well as the processes that determine them in the subsurface prior to drilling. The impact of rock strength relative to fluid pressure at depth will also be discussed, in relation to injection rate limitations and storage volumes.

Duration and Logistics

Classroom version: A 3-day course comprising a mix of lectures, case studies and exercises. The manual will be provided in digital format and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Virtual version: Five 3.5-hour interactive online sessions presented over 5 days. A digital manual and exercise materials will be distributed to before the course. Some reading and are to be completed by participants off-line.

Level and Audience

Advanced. Intended for geoscientists and engineers who are involved in drilling into reservoirs for the purpose of injecting, storing and producing fluid. Some knowledge of subsurface geology and the basics of drilling wells would be an advantage.

Objectives

You will learn to:

  1. Understand how subsurface pressures determine safe injection, storage and production from deep reservoirs.
  2. Appreciate the processes that govern safe drilling, with particular emphasis on pore fluid and fracture pressures.
  3. Describe how to analyze subsurface pressure data and calibrate to estimate pore pressures from a variety of drilling and logging data.
  4. Relate regional and local rock stress magnitudes to failure of seals.
  5. Evaluate how to assess volumes that can be safely sequestered in underground storage.
  6. Interpret typical pressure profiles, in terms of subsurface fluid processes, such as lateral drainage (open aquifers) and lateral transfer (enhanced pressures and a drilling surprise).
  7. Perform basic pressure prediction calculations and estimate storage volumes.
  8. Review and critique relevant case study material.

Critical Minerals for the GeoEnergy Transition (G503)

Tutor(s)

Lucy Crane: ESG and Sustainability Consultant.

Overview

This course covers all aspects of the crucial role that mineral extraction will play in the energy transition. Building the low-carbon technologies required to combat climate change, such as wind turbines, electric vehicles and batteries, will be hugely mineral intensive. The impact of this increased extraction is often overlooked, yet it’s vital that these materials are sourced and extracted in the most responsible manner possible. This course explores where certain critical raw materials are currently produced and the impacts of their global supply chains, as well as examining how new technologies are aiding exploration for and extraction of new deposits. It also discusses challenges faced by responsible sourcing, and the growing importance of ESG within the mining industry.

Duration and Logistics

Classroom version: A 1.5-day course comprising a mix of lectures, case studies and exercises. The manual will be provided in digital format and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Virtual version: Three 3.5-hour interactive online sessions presented over 3 days. A digital manual and exercise materials will be distributed to participants before the course. Some reading and exercises are to be completed by participants off-line.

Level and Audience

Fundamental. The course is intended for industry professionals, though it is suitable for penultimate year undergraduate university students and above.

Objectives

You will learn to:

  1. Understand the wider context behind the mineral intensity of the energy transition.
  2. Define what is a ‘critical’ raw material.
  3. Describe how new technologies are ‘unlocking’ mineral deposits which have previously been considered unconventional.
  4. Understand the technical challenges associated with production of certain critical raw materials.
  5. Describe how environmental, social and geopolitical factors can also influence an element’s ‘criticality’.
  6. Begin to evaluate the environmental and social impacts of current global supply chains.
  7. Understand the role mineral extraction has to play in delivering the UN Sustainable Development Goals, alongside various industry operating codes and principles.
  8. Assess the importance of Environmental, Social and Governance (ESG) factors in project success.

Carbon Capture and Storage Masterclass (G502)

Tutor(s)

Richard Worden: Professor in the Department of Earth Ocean and Ecological Sciences, University of Liverpool, UK.

Overview

This course will provide participants with awareness of the geoscience needs for CCS projects; namely subsurface CO2 storage volumetrics, CO2 flow in the subsurface away from injector wells, the goal of safe and permanent storage of CO2 and cost-benefit issues linked to aquifer depth, well design, etc. The course will establish basics, such as how much CCS is needed to make a difference to global warming, and explore what types of CO2 injection are already happening, including information from CO2-enhanced oil recovery projects. The course will deal with CO2 as a fluid phase and how much CO2 can be stored per cubic meter in terms of porosity and over entire aquifers. It will deal with how quickly CO2 can be injected and the role of aquifer permeability. The course then moves on to the all-important geomechanical effects of CO2 injection and feedbacks between induced mineral dissolution and rock strength and other rock properties. The full range of possible interaction between CO2 and both aquifer and top-seal will be covered, as will the range of possible leakage mechanisms that need to be assessed. The course will conclude with consideration of monitoring strategies.

Duration and Logistics

Classroom version: A 3-day course comprising a mix of lectures, case studies and exercises. The manual will be provided in digital format and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Virtual version: Five 3.5-hour interactive online sessions presented over five days. Digital course notes and exercise materials will be distributed to participants before the course. Some exercises may be completed by participants off-line.

Level and Audience

Intermediate. The course is largely aimed at geoscientists, but engineers will also find the course instructive. Intended for sub-surface scientists, with an emphasis on geoscience topics. Participants will probably have a working knowledge of petroleum geoscience. However, the subject matter of this course, the geoscience of carbon capture and storage, is covered from basic principles.

Objectives

You will learn to:

  1. Develop awareness of the role of geoscience in CCS and of CCS in CO2 emissions reductions.
  2. Appreciate what CO2 injection projects have occurred so far and how they differ from industrial CCS.
  3. Understand CO2 as a fluid in the subsurface and the fluid injection pressure and effective stress regimes that CO2 injection will involve.
  4. Build awareness of the volumetrics of CO2 storage from the micro (pore-scale) to the macro (aquifer volumes).
  5. Gain an appreciation of the question of CO2 flow away from injector wells controlled by permeability and aquifer architecture.
  6. Understand the range of effects that CO2 can have on the host aquifer, from geomechanical to geochemical.
  7. Assess the role of top-seal and fault-seal properties and how they will influence CO2 storage, from risk of fracking, or induced seismicity, to mineral dissolution.
  8. Understand the range of ways that CO2 could escape from the planned storage sites.
  9. Develop an awareness of the range of monitoring strategies that could be employed to ensure safe and long-term storage of CO2.

Best Practices in Pore Pressure and Fracture Pressure Prediction (G043)

Tutor(s)

Richard Swarbrick: Manager, Swarbrick GeoPressure.

Overview

This course presents best practices in how data and standard techniques are combined to generate meaningful pore pressure (PP) and fracture pressure (FG) estimates from log, seismic and drilling data, and to use them to develop pre-drill predictions. The limitations are addressed, along with common pitfalls, leading to an understanding of the uncertainty and risk associated with PP and FG prediction.

The course begins by showing the types and reliability of subsurface data used to inform current knowledge, which will also calibrate PP and FG predictions at a remote location. Standard approaches to PP and FG prediction techniques are taught, with careful attention to where these have limitations on account of subsurface environment (thermal, tectonic) and data quality. A new approach to PP prediction using shales is taught as an independent guide to expected PP, especially valuable where only seismic data are available. Prediction of FG is taught by showing how to determine overburden stress and apply standard relationships, including new approaches with PP-stress coupling.

Duration and Logistics

Classroom version: A 2-day classroom course comprising a mix of lectures and discussion (90%) and exercises (10%). The manual will be provided in digital format, and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Virtual version: Four 3.5-hour interactive online sessions presented over 2 to 4 days. A digital manual and exercise materials will be distributed to participants before the course. Some reading and several exercises are to be completed by participants off-line.

Level and Audience

Intermediate. Intended for exploration and development geoscientists, petrophysicists, operations staff and drilling engineers. Familiarity with oilfield data and drilling practices is required. Experience shows that mixed classes of geoscientists and engineers benefit particularly from the discussions and sharing of approaches in this multi-disciplinary area of work.

Objectives

You will learn to:

  1. Distinguish the different types and quality of data that populate pressure-depth and EMW-depth plots for display of pressure predictions and calibration data in well planning.
  2. Use best practice to create PP estimations and predictions from seismic, log and drilling data using standard porosity-based techniques, and from modelling geological systems.
  3. Use best practice to create FG estimations and predictions by generating an overburden and establishing its relationship with FG and PP.
  4. Communicate Min-Expected-Max predictions effectively to both geoscience and engineering/operations staff involved in well planning.

Workflows for Seismic Reservoir Characterization (G004)

Tutor(s)

Patrick Connolly: Director, Patrick Connolly Associates; Visiting Lecturer, University of Leeds, UK.

Overview

This course will provide participants with the skills needed to design and implement workflows for seismic reservoir characterization using established best-practice and emerging technology. The course covers seismic conditioning, colored inversion, AVO theory including elastic and extended elastic impedance, DHIs, seismic net pay, well ties, rock physics and deterministic and probabilistic inversion, including the application ODiSI.

Duration and Logistics

A 4-day classroom course comprising a mix of lectures with examples (70%) and laptop-based exercises and discussion (30%). The manual will be provided in digital format and participants will be required to bring a laptop or tablet computer to follow the lectures and exercises.

Level and Audience

Advanced. Intended for practicing seismic interpreters. Participants should have a basic knowledge of the seismic method, including acquisition and processing, with a minimum of three years working with seismic data. However, the subject matter of this course, AVO and inversion, is covered from basic principles.

Objectives

You will learn to:

  1. Appreciate the benefits of colored inversion – how and why it works and how to get the best results from a colored inversion application.
  2. Understand the relationships between reflectivity and impedance, and between time and frequency.
  3. Understand the model for AVO measurements and the difficulties in making accurate AVO measurements.
  4. Understand the concepts behind AVO analysis, including intercept-gradient crossplots and the theoretical relationship between elastic and AVO properties.
  5. Optimize AVO products for subsequent characterization work and create seismic products that correlate with specific reservoir properties.
  6. Appreciate the risks of using attributes with no physical relationship with the desired objective.
  7. Appreciate the limitations of the seismic net pay method and to know when it is, and is not, applicable.
  8. Understand the principles and pros and cons of deterministic and probabilistic inversion and how to select the appropriate inversion strategy for any given problem.