Oil and Gas

Oil and Gas | Clastics

Basin-Scale Analysis of a Confined Turbidite System (Grès d'Annot, SE France)

Course Code: N112
Instructors:  Gillian AppsDavid Stanbrook
Course Outline:  Download
Format and Duration
6 days

Summary

This courses analyses the initiation, fill history and links between a suite of structurally confined deepwater sub-basins, with reference to local and regional scale facies and stratigraphic architecture. The course aims to enhance understanding of subsurface deepwater basins that are confined by structures related to salt- or mud-deformation, faults and fault-related topography. 

Feedback

A highly integrated comprehensive course that presents the basin scale architecture clearly, and augmented large scale relationships with detailed facies description. Really enjoyed the course - learned a lot. Exceptionally good presentation of geography.

Duration and Training Method

A six-day field course, based in the French Alps. 90% of the time will be spent in the field, making active observations singly, and in small teams. A 3D grid of restored structural cross sections are used to provide the structural framework for the linked mini-basins. Photos are used for seismic-scale observations, with logged sections of the outcrop for well-scale, and hands-on study of core-scale bed patterns and facies. Participants will analyse proximal-distal variations within single sub-basins and between mini-basins, and compare a range of mini-basin margins settings. Case studies of subsurface examples of confined mini-basins are used, both in the field and classroom.

Course Overview

Participants will learn to:

    1. Assess discrete, structurally controlled sediment transport pathways into bathymetrically complex deepwater basins.
    2. Evaluate the role of basin initiation and closure as external controls on basin fill and remobilization sequences.
    3. Assess the role of relative structural and flow confinement on turbidite reservoir and seal facies, reservoir stacking patterns, and stratigraphic architectures.
    4. Characterise different reservoir architectures in a series of mini-basins from proximal, shallow marine, through base of slope to mid and distal basin settings.
    5. Characterise the range of bed-scale deposits from low density to high-density turbidites, linked turbidite-debrite deposits, and multiple scales of sediment remobilization.
    6. Assess the role of active structures, beneath and within the turbidite basin, on slope instability, and predict impact of seismic-scale reservoir heterogeneity (mass transport complexes) on reservoir performance.
    7. Validate and combine established models for structurally confined basins and consider the subsurface implications of the different models for linkage between mini-basins.
    8. Predict different basin margin onlaps and assess related stratigraphic trap definition and seal integrity risks.

    All subsurface geoscientists evaluate confined deepwater basins using a combination of seismic, well, core and existing production data. This course aims to provide structural stratigraphic tools and techniques for analysing these basins by using outcrop examples of an analogous suite of linked deepwater minibasins. Observations, discussion and prediction in the field range from large (seismic) scale to small (core) scale. At all times, participants will make outcrop observations in the context of subsurface data, in plays from deepwater fold and thrust belts, rift and early post-rift settings and salt provinces.

    The Grès d’Annot includes a range of bed-scale deposits: low and high concentration turbidites, debris flows as well as slumps and slides. Deepwater reservoir architectural elements discussed will include: thin- and thick-bedded turbidite lobes, turbidite channels, seismic-scale mass transport units, and reservoir bodies in basin margin onlap settings.

    As the course progresses, participants will gain an appreciation of the different reservoir architecture within, and between individual sub-basins, and be in a position to predict the factors controlling these differences. This will lead to an improved understanding of the distinctions between partially confined and ponded basins, and the effects of confinement on bed-scale deposits, architecture, reservoir stacking patterns and stratigraphic basin-fill sequences. At every stage in this course, the implications for reservoir presence and deliverability, seal presence, and stratigraphic trap integrity are predicted and considered within the constraints of data available to subsurface geoscientists in different parts of the value chain.

    Day 0
    Arrival in Nice and transfer to hotel.
    Evening course safety brief and introductory talk followed by group dinner.

    Day 1
    Analysis of the up-dip, basin margin feeder system to the Gres d’Annot basin and its potential impact on sediment delivery to the deepwater system. Location of the principal deepwater sediment transport pathways of the Gres d’Annot and controls on their position.

    Day 2
    Initiation of the Grès d’Annot basin: brief examination of deformed Cretaceous limestones and base Tertiary unconformity, and the deepening sequence of Calcaire Nummulitique and Marnes Bleues culminating in the deposition of Grès d’Annot turbidites.

    Analysis of key localities that define the nature of the proximal Annot sub-basin and its fill succession. Seismic-scale examination of high net:gross architectures followed by closer inspection of onlap facies characteristics. Initial discussion of alternative interpretations of the Annot sub-basin as either a through-going channel complex, or a confined or ponded basin.

    Day 3
    Sedimentology and depositional architectures of a high net:gross sheet-like system and channels. Examination of late stage extensional faults in Grès d’Annot. Discussion of sheeted seismic facies and its significance in subsurface deepwater systems.

    Col de la Cayolle: Termination of the basin phase with Grès d’Annot turbidite deposition halted and eroded into by the Schiste-a-Bloc – a thrust propagated, seismic scale mass transport complex with large scale debris flows, olistoliths on decametre to kilometre scale.

    Day 4
    Annot: Examination of major syn-depositional fault within the proximal Annot sub-basin. Close inspection of high-density turbidity current deposits within a strongly confined conduit. Onlap surfaces close to the potential spill point between the proximal Annot sub-basin and the medial Grand Coyer sub-basin. Generic discussion of spill point characteristics in subsurface confined basins.

    Day 5
    Grand Coyer: Analysis of three-dimensional sandstone bodies and stacking pattern characteristics of the turbidite system in the medial Grand Coyer sub-basin; insights into different scales of heterogeneity within a sand-rich turbidite system. Observations on lateral facies variations from sub-basin margin to sub-basin axis, including the effects of gravitational growth faulting.

     

    Day 6
    Montagne de Chalufy: Anatomy of onlap surfaces at the margins of a distal sub-basin, axial to lateral changes in depositional elements and sand-bodies, and precise nature of sand-body terminations onto the onlap surface. Discussion of the seismic expression of onlap surfaces and onlap plays in sub-surface confined basins. Deepwater channel architecture and filling styles.

    Discussion on the links between the Grès d’Annot proximal, medial and distal sub-basins and relation to ‘fill and spill’ basins.

    Day 7
    Return to Nice and departure.

    The course is specifically designed for geologists and geophysicists evaluating exploration provinces or fields in deepwater confined basins, within deepwater fold and thrust belts, rift and early post-rift settings and salt provinces. Experienced reservoir engineers can also derive a deeper knowledge of the geological parameter ranges that underpin simulation models.

    Gillian Apps

    Background
    Gillian has worked as a geoscientist in the hydrocarbon industry for 34 years, for Shell, BP and BHP Billiton. She is currently an independent geoscientist, with specialist skills in sedimentology, and deep experience in structurally complex basins (salt provinces, deepwater fold belts and rift basins). Most of her career opportunities were in the Gulf of Mexico (both US and Mexican waters), Trinidad, the North Sea, and South Atlantic hydrocarbon provinces.

    Her experience includes a wide variety of subsurface geoscience positions, from frontier basin play fairway analysis, through prospect generation, to resource appraisal, project development and oil & gas production. She started her career as a production geophysicist with Shell, with a degree in Earth Sciences from Cambridge; after three years, she returned to university to undertake doctorate research on the structural and stratigraphic evolution of the Grès d’Annot turbidite basin, supervised by Professor Trevor Elliott.

    Since then, she has managed a dual career with her husband Dr Frank Peel, living with their two daughters and working in London, Houston, Melbourne and briefl y, Mexico City and Beijing. Gillian enjoys balancing work with high school STEM outreach programs in Texas and the UK. She now lives and works in the New Forest, UK.

    Affiliations and Accreditation
    PhD University of Liverpool - Geology
    MA University of Cambridge - Natural Sciences

    Courses Taught
    N112: Basin-Scale Analysis of a Confi ned Turbidite System (Grès d’Annot, SE France)

    David Stanbrook

    Background
    Stan has over sixteen years’ experience working in deep-water clastic (turbidite) systems beginning with ten years based in outcrops. Initial outcrop work was done whilst at Heriot-Watt where he worked on a range of depositional systems in different basinal settings and also completed his PhD. He continued his outcrop experience at Nautilus by managing their portfolio of deep-water clastic courses and also realized a passion for teaching through the above courses – both of which have run successfully each year since 2007.

    Moving into the subsurface in 2008 with Maersk Oil in Copenhagen, and later Aberdeen, Stan undertook exploration work in Denmark and the UK. At the same time Stan carried out projects as a turbidite specialist for exploration and development projects in the same countries as well as Norway, Angola and the Gulf of Mexico. Recently Stan has moved to Kuala Lumpur as a Geological Advisor to Murphy Oil undertaking New Ventures activities in South East Asia.

    Stan’s technical interests lie in the interaction of turbidity currents with complex topography and the resultant architectural and facies and their relation to reservoir distribution and performance. Outside the technical Stan has interests in diving (facilitated by the recent move to Asia) and walking in the clear mountain air (somewhat hampered by the recent move to Asia).

    Affiliations and Accreditation
    PhD Heriot Watt University in Edinburgh - Turbidite Sedimentology
    BSc University of Bedfordshire - Geology

    Courses Taught
    N033: Characterisation, Modelling, Simulation and Development Planning in Deepwater Clastic Reservoirs (Tabernas,Spain)
    N112: Basin-Scale Analysis of a Confined Turbidite System (Grès d’Annot, SE France)

    CEU: 4.8 Continuing Education Units
    PDH: 48 Professional Development Hours
    Certificate: Certificate Issued Upon Completion
    RPS is accredited by the International Association for Continuing Education and Training (IACET) and is authorized to issue the IACET CEU. We comply with the ANSI/IACET Standard, which is recognised internationally as a standard of excellence in instructional practices.
    We issue a Certificate of Attendance which verifies the number of training hours attended. Our courses are generally accepted by most professional licensing boards/associations towards continuing education credits. Please check with your licensing board to determine if the courses and certificate of attendance meet their specific criteria.