2018/19 Taught Postgraduate Module Catalogue
SOEE5174M Integrated Sub Surface Analysis
30 creditsClass Size: 30
Module manager: Dr Emma Bramham
Email: E.K.Bramham@leeds.ac.uk
Taught: Semester 2 (Jan to Jun) View Timetable
Year running 2018/19
Pre-requisite qualifications
MSc entrance qualificationsThis module is mutually exclusive with
| SOEE5128M | Petrophysics & GP Reservoir Ev |
| SOEE5171M | Seismic Reflection Interp |
Module replaces
Replaces SOEE5171M and SOEE5128M for MSc Structural Geology ONLYThis module is not approved as an Elective
Module summary
This module provides theoretical and practical learning with the module focusing on integrating a suite of sub-surface data into a common data set to allow for the learning and skills achieved in parts A,B and C (see below) to be integrated in the final part D of the module, providing the student with a full understanding of how each component works together.The module is divided into four partsA) Petrophysics and borehole analysisB) Seismic Reflection interpretation and sequence stratigraphyC) Geocellular model construction and evaluation of structural Geology implications D) The final component of the module consists of an integrated practical where by a suite of data is provided and students, within a group environment, are expected to integrate these data and make an industry-style report on asset.Objectives
On completion of this module students should be able to understand the underlying principals behind borehole data, seismic reflection data and fault models. They should be able to take these diverse data and integrate them into a single dataset. This will provide the opportunity to investigate how these different techniques are integrated in a workflow typical in both industry and the final independent research project.Learning outcomes
In Part A students should be able to understand the fundamentals of petrophysics and its use in the analysis of cores and geophysical well logs for reservoir characterisation and hydrocarbon assessment. They should have acquired skills in the analysis of geophysical well logs for determining lithology, porosity and hydrocarbon saturation.
In Part B the student will be able to understand the principles and practice of interpreting seismic reflection data, in both a general geological and structural context and in a detailed sequence-stratigraphic context. The student will be able to produce 3D-based geological models by interpreting 2D seismic lines and 3D seismic cubes, both using paper sections and computer-based software.
In Part C students should be apply industry-standard 3D modelling/visualisation packages to building structural models and considered relationship between model horizons and faults. They should be able to construct 3D geo-cellular models and considered their application.
In Part D students will integrate the learning outcomes from Parts A-C using a single dataset and produce an industry style report. This will be undertaken as a group exercise to highlight the importance of team work in industry.
Syllabus
Part A
Petrophysics
- Formation Evaluation: geoelectrical properties
- Resistivity borehole logging
- Induction and SP logs
- Porosity Logs: sonic and density
- Porosity Logs: neutron and natural gamma ray
- Magnetic Nuclear Resonance Logs
- Image Logs and determination of lithology and porosity
- Fracture Analysis and seismic anisotropy
- Vertical Seismic Profiles (VSP): field procedures, travel-time relationships
Part B
Seismic interpretation:
- Context of reflection seismic data and basic principles of interpretation using hand and computer algorithms
- Use of seismic attributes for quantitative interpretation
- Seismic-to-well tie
- Velocity models, depth conversion and uncertainty analysis
Sequence stratigraphy:
- Sequence stratigraphy and chronostratigraphy for siliclastic sediments
- Linking seismic interpretation of sequence stratigraphy to well and outcrop parasequences
- Introduction to carbonate sequence stratigraphy
- Strategy and workflow for quantitative interpretation (seismic facies).
Part C
- The generation and interrogation of a faulted 3d geological data set within the 3D modelling programme, Petrel.
- Creating 3D surfaces and faults, geocellular volumes.
Part D
- Integrate the learning outcomes from Parts A-C using a single data in a group setting with minimum support provided by staff.
Teaching methods
| Delivery type | Number | Length hours | Student hours |
| Group learning | 1 | 60.00 | 0.00 |
| Lecture | 20 | 1.00 | 20.00 |
| Practical | 30 | 2.00 | 60.00 |
| Tutorial | 2 | 1.00 | 2.00 |
| Private study hours | 218.00 | ||
| Total Contact hours | 82.00 | ||
| Total hours (100hr per 10 credits) | 300.00 | ||
Private study
Private study will be for completion of practicals, assessments and final reports (to include literature searches, reading text books, computer excercises) and revision for examinationsOpportunities for Formative Feedback
Progress will be monitored by assessment and feedback throughout.Methods of assessment
Coursework
| Assessment type | Notes | % of formal assessment |
| Report | Part D - Individual Project Report | 35.00 |
| Practical | Part A – 2 x Assessed Practical | 20.00 |
| Practical | Part B - 3 x Assessed Practical | 40.00 |
| Presentation | Part D - 1 x Group Presentation | 5.00 |
| Total percentage (Assessment Coursework) | 100.00 | |
Part A (Petrophysics) – 6 credits; Part B (Seismic reflection + Seismic Stratigraphy) - 12 credits; Part C (Petrel) – 4 credits (assessment for this will be included within the Integrated Practical (part D) final report); Part D (Integrated Practical) – 8 credits
Reading list
The reading list is available from the Library websiteLast updated: 03/09/2018
Browse Other Catalogues
- Undergraduate module catalogue
- Taught Postgraduate module catalogue
- Undergraduate programme catalogue
- Taught Postgraduate programme catalogue
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