Carbonate Reservoir Characterization
|Laura Galluccio or Thomas Haines (Badley Ashton, United Kingdom)|
|Geology – Carbonate Geology|
|5 CPD points|
CARBONATES RESERVOIR CHARACTERIZATION SEDIMENTOLOGY STRATIGRAPHY
Next available location:
This carbonate reservoir characterization course focuses on the analysis of carbonate depositional textures and the subsequent diagenetic modifications as the main controls on the pore system evolution, heterogeneity and complexity. The intricate inter-relationship of the depositional and burial history can be unravelled to allow the prediction of reservoir facies, and hence, aid reconstruction and development of three-dimensional reservoir models. This course demonstrates the value of understanding pore system evolution as a part of large-scale volumetric assessments and the development of carbonate reservoirs.
Reservoir quality in carbonate successions is often defined by the storage capacity, flow potential (ie. porosity and permeability respectively, measurements that are often acquired during conventional core analysis) and connectivity of pores (recorded as the pore-throat radius distributions during special core analysis). The interplay between these quantifiable factors (including sample-scale heterogeneities) is inevitably linked to the original depositional characteristics of the carbonate sediments, together with their susceptibility to post-depositional diagenetic alteration, which results in the ultimately complex pore system. Therefore, the classification of individual pore types will be detailed in this course, with their primary depositional or secondary diagenetic origin being discussed in context with sedimentological and stratigraphic models in order to underpin their spatial relationships and potential connectivity. In addition, the characterization of micrite textures will be discussed to illustrate their impact on the microporosity, factors that are particularly important to consider in tight unconventional reservoirs.
The depositional controls on reservoir properties that will be taken into consideration in this course include the texture, grain size, clay and matrix content as well as the type and quantity of allochems. The relationship between dissolution processes that result in an enhancement of the pore system, cementation processes that reduce the pore volume and the resultant connectivity and fluid flow pathways will be assessed to constrain the dominant diagenetic controls on the reservoir properties. In addition to this, the process of dolomitisation will be scrutinised in order to determine if and how this process enhances and/or reduces reservoir properties.
Integrating the key controls on reservoir quality within the sedimentological framework enables the establishment of a conceptual reservoir architecture model, which can be used to assess and predict the vertical and lateral variations in porosity and permeability at the reservoir and/or field scale. This course outlines how to conceptually build a reservoir architecture model, which in turn can be used to aid reservoir modelling.
This course will be accompanied by a series of in-class exercises, which will emphasize the integration of the various datasets, providing participants with experience in carbonate reservoir characterization.
Upon completion of the course, participants will be able to:
- Identify the different pore types, their interconnectivity and hence the impact on permeability;
- Determine how specific sedimentological parameters and diagenetic process impact reservoir quality;
- Understand sample heterogeneity and its impact on reservoir quality data;
- Upscaling of reservoir quality data to aid prediction at the field scale.
The course will be organised into three sessions:
Part A: Reservoir quality analysis - What it is and how to approach it
- Definition of reservoir quality;
- How to characterise reservoirs.
Part B: Pore types and connectivity
- Concepts and definitions;
- The carbonate pore type classification(s);
- Permeability and pore-throat radius distributions;
- Manipulating reservoir quality data;
- Introduction to advanced reservoir quality tools.
Part C: Controls on reservoir quality
- Sample heterogeneity;
- Sedimentological controls;
- Diagenetic controls;
- Reservoir architecture construction.
Each section will be accompanied by examples from case history exercises.
This course is designed for petroleum geologists, geoscientists, petrophysicists and engineers involved in exploration and production of carbonate plays.
Although previous knowledge on carbonate sedimentology is not necessarily required, participants should have some knowledge of geology.
About the instructor
Laura Galluccio (Ph.D.) is one of Badley Ashton's UK-based senior carbonate reservoir geologists with an interest in carbonate petrography and sedimentology. She specialises in sedimentology, diagenesis and reservoir quality characterization of limestones and dolomites in both conventional and unconventional reservoirs. She has wide experience in the Middle East, the USA, Europe and Africa. The projects she has been involved in cover a wide range of depositional environments from shallow to deeper water carbonates. Laura received his BSc, MSc and PhD at the University of Naples (Italy), with her PhD conducted in conjunction with Shell Italy. As an effective communicator and with a proven track record of excellent client care, past roles include Team Leader of the Carbonate Group, and local Business Manager and Consultant Geologist based in PDO's offices, Muscat. Since her appointment as Regional Manager in August 2017, Laura oversees business activity in the Middle East, Africa and Asia, supported by regional Operations and Portfolio Managers. Laura's other research interests include sedimentology and sequence stratigraphy of ancient and recent carbonate platforms and the characterization of diagenetic processes affecting carbonate sediments with integration into the regional framework and influence on the pore system. She is currently involved in research on the diagenesis and pore volume assessment of Hyamm Formation in Oman in collaboration with the Ferrara University and Sultan Quaboos University, as well as a project focused on the role of hydrocarbons emplacement for calcite precipitation, in collaboration with Newcastle University. Laura has undertaken teaching of geological mapping, petroleum geology and reservoir quality evaluation at both BSc and MSc levels, while co-supervising a variety of BSc and MSc carbonate research projects.
Thomas Haines (Ph.D) is a carbonate reservoir geologist with an interest in sedimentology and petrography with experience in the Middle East and Europe. He specializes in carbonate sedimentology and diagenesis using a range of techniques from the core and BHI-scale to the SEM-scale. He has notable experience of Cenozoic and Mesozoic carbonate deposits in the Mediterranean and Middle East regions, respectively. In his Ph.D work, Thomas gained experience in the sedimentological, diagenetic and petrophysical characterization of carbonate-hosted fault zones. Thomas is currently working on single-well and multi-well reservoir quality evaluation studies dealing with carbonate plays of the Arab Gulf. These projects cover a wide range of depositional environments from shallow to deeper water carbonates.
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