Loading...
NEW
68
0
Course code: 000590
School of Engineering
GEOP007 - Analysis of Structural Traps in Extensional Settings
0.0
0 ratings
0 students
Upcoming sessions
Date Location Language Format Price
Currently, this course is conducted only in an intracorporate format.
Special Offer
Competencies
What this course about?

The "Analysis of Structural Traps in Extensional Settings" training program is an intensive course designed to equip participants with the essential principles, techniques, and real-world applications related to structural traps in extensional settings. Extensional terranes, being one of the most common structural styles, form the foundation of many continental and deepwater margins and host some of the world's largest oil provinces. The advent of 3D seismic technologies has revolutionized structural mapping, making this course vital for professionals and students in the oil and gas industry.

The training program covers a range of topics, including extensional structural styles and their development, elements of extensional systems in 2D and 3D views, and the impact of structural relief on depositional systems. Participants will learn about restoration and validation techniques, fracture mechanics in extensional environments, and the factors affecting fault sealing in hydrocarbon exploration.

Throughout the course, delegates will engage in hands-on exercises such as seismic interpretation tasks and field studies to reinforce the concepts learned. By the end of the training program, participants will be well-equipped to make informed decisions and enhance their skills in hydrocarbon exploration and development projects in extensional terranes, staying up-to-date with the latest advances and techniques in this critical area of the oil and gas industry.

Who is this course for?
This course is designed for professionals and students involved in the oil and gas industry, particularly those who are interested in the exploration and development of hydrocarbon resources in extensional settings. The target audience includes:
• Geoscientists: Geologists, Geophysicists, and Petrophysicists who are involved in the exploration, appraisal, and development of hydrocarbon resources in extensional basins.
• Reservoir Engineers: Professionals responsible for understanding reservoir architecture, dynamics, and performance in extensional settings.
• Structural Geologists: Researchers and professionals focused on the analysis and interpretation of structural geology in extensional terranes.
• Geoscience students: Undergraduate and graduate students pursuing degrees in geology, geophysics, or related disciplines who are interested in specializing in structural geology or hydrocarbon exploration in extensional settings.
• Exploration Managers and Team Leads: Decision-makers responsible for guiding exploration strategies and managing exploration projects in extensional basins.
• Academics and Researchers: Professionals working in academic or research institutions who are interested in understanding the fundamental processes and techniques involved in the analysis of structural traps in extensional settings.
• Service Company Professionals: Technical experts from service companies providing specialized services, such as seismic data acquisition, processing, or interpretation, in extensional settings.
By attending this course, participants will gain a comprehensive understanding of the fundamental principles, techniques, and real-world applications related to the analysis of structural traps in extensional settings. This knowledge will enable them to make informed decisions and enhance their skills in hydrocarbon exploration and development projects in these terranes.
What will you learn?
  • Understand the fundamental principles and processes governing the formation and evolution of extensional terranes and their associated structural traps
  • Recognize and classify various types of extensional structural styles and their relationship with other structural styles
  • Analyze and interpret structural elements in extensional systems, including fault linkage, relay ramps, intrabasinal geometries, and full and half grabens
  • Apply 3D seismic interpretation techniques to better understand the structural architecture and development of extensional basins
  • Utilize kinematic and restorative thinking to validate structural interpretations and predict basin evolution in extensional settings
  • Evaluate the impact of depositional systems on reservoir quality and trapping mechanisms in extensional terranes
  • Comprehend the basics of fracture mechanics and fault sealing processes in extensional environments, and their implications for hydrocarbon exploration and production
  • Identify and assess the potential of structural traps in extensional settings using real-world examples and case studies
  • Apply the knowledge gained from the course to make informed decisions and enhance exploration strategies in extensional basins
  • Effectively communicate and collaborate with multidisciplinary teams involved in hydrocarbon exploration and development projects in extensional settings
Course outline
  • Course objectives and overview
  • Importance of extensional terranes in hydrocarbon exploration
  • Overview of structural traps in extensional settings
  • Different types of extensional terranes and their development
  • Relationships between extensional and other structural styles
  • Rift initiation and development
  • Transition from rift basin to passive margin
  • Influence of salt and strike-slip tectonics on basin development
  • Fault linkage and relay ramps
  • Intrabasinal structural geometries
  • Full and half grabens and their associated features
  • Seismic data acquisition and processing in extensional settings
  • Use of 3D seismic data for structural interpretation
  • Integration of outcrop, subsurface, and seismic data
  • Principles of kinematic and restorative thinking
  • Restoration algorithms for extensional systems
  • Validation of structural interpretations
  • Influence of structural relief on depositional systems
  • Terrestrial and marine depositional environments
  • Impact of depositional systems on reservoir quality
  • Fundamentals of fracture dynamics in extensional settings
  • Evolution of extensional faults and fracture systems
  • Factors affecting fault sealing and implications for hydrocarbon exploration
  • Types of traps associated with extensional geometries
  • Case studies of successful hydrocarbon exploration in extensional terranes
  • Deformational effects on reservoir quality and trapping mechanisms
  • Seismic interpretation exercises
  • Field studies and outcrop analysis
  • Restoration and validation exercises
  • Key takeaways from the course
  • Future trends and challenges in extensional settings exploration
  • Closing remarks and Q&A session
Eni
Total
Eni
Endesa
Shell
Chevron
Gas Natural
Iberdrola
Eni
Inpex
Eni
Exonmobile

Training can take place in 4 formats:

  • Self-paced
  • Blended learning
  • Instructor-led online (webinar)
  • Instructor-led offline (classroom)

Description of training formats:

  • Self-paced learning or e-Learning means you can learn in your own time and control the amount of material to consume. There is no need to complete the assignments and take the courses at the same time as other learners.
  • Blended learning or "hybrid learning" means you can combine Self-paced learning or e-Learning with traditional instructor-led classroom or webinar activities. This approach requires physical presence of both teacher and student in physical or virtual (webinars) classrooms or workshops. Webinar is a seminar or presentation that takes place on the internet, allowing participants in different locations to see and hear the presenter, ask questions, and sometimes answer polls.
  • Instructor-led training, or ILT, means that the learning can be delivered in a lecture or classroom format, as an interactive workshop, as a demonstration under the supervision and control of qualified trainer or instructor with the opportunity for learners to practice, or even virtually, using video-conferencing tools.

When forming groups of students, special attention is paid to important criteria - the same level of knowledge and interests among all students of the course, in order to maintain stable group dynamics during training.

Group dynamics is the development of a group in time, which is caused by the interaction of participants with each other and external influence on the group. In other words, these are the stages that the training group goes through in the process of communicating with the coach and among themselves.

The optimal group size for different types of training:

  • Self-paced / E-learning: 1
  • Instructor-led off-line (classroom): 6 – 12
  • Instructor-led on-line (webinar): 6 – 12
  • Blended learning: 6 – 12
  • Workshop: 6 – 12
  • On-the-job: 2 – 4
  • Simulator: 1 – 2

Feedback in the form of assessments and recommendations is given to students during the course of training with the participation of an instructor and is saved in the course card and student profile.

In order to control the quality of the services provided, students can evaluate the quality and training programme. Forms of assessment of the quality of training differ for courses with the participation of an instructor and those that are held in a self-paced format.

For courses with an instructor, start and end dates are indicated. At the same time, it is important to pay attention to the deadlines for passing tests, exams and practical tasks. If the specified deadlines are missed, the student may not be allowed to complete the entire course programme.

A personal account is a space for storing your training preferences, test and exam results, grades on completed training, as well as your individual plan for professional and personal development.

Users of the personal account have access to articles and blogs in specialized areas, as well as the ability to rate the completed training and leave comments under the articles and blogs of our instructors and technical authors

Registered users of a personal account can have various roles, including the role of a student, instructor or content developer. However, for all roles, except for the student role, you will need to go through an additional verification procedure to confirm your qualifications.

Based on the results of training, students are issued a certificate of training. All training certificates fall into three main categories:

  • Certificate of Attendance - students who successfully completed the course but did not pass the tests and exams can apply for a certificate of attendance.
  • Certificate of Completion - students who have successfully completed a course could apply for a Certificate of Completion, this type of certificate is often required for compliance training.
  • Verified Certificate - it is a verified certificate that is issued when students have passed exams under the supervision of a dedicated proctor.

You can always download a copy of your training certificate in PDF format in your personal account.

You will still have access to the course after completing it, provided that your account is active and not compromised and Tecedu is still licensed for the course. So if you want to review specific content in the course after completing it, or do it all over again, you can easily do so. In rare cases, instructors may remove their courses from the Tecedu marketplace, or we may need to remove a course from the platform for legal reasons.

During the training, you may encounter various forms of testing and knowledge testing. The most common assessment methods are:

  • preliminary (base-line assessment) - to determine the current level of knowledge and adapt the personal curriculum
  • intermediate - to check the progress of learning
  • final - to complete training and final assessment of knowledge and skills, can be in the form of a project, testing or practical exam

Travel to the place of full-time training is not included in the cost of training. Accommodation during full-time studies can be included in the full board tuition fees.

While Tecedu is not an accredited institution, we offer skills-based courses taught by real experts in their field, and every approved, paid course features a certificate of completion or attendance to document your accomplishment.

You can preview samples of the training materials and review key information about the course on our website. You can also review feedback and recommendations from students who already completed this course.

We want you to be happy, so almost all purchased courses can be returned within 30 days. If you are not satisfied with the course, you can request a refund, provided the request complies with our return policy.

The 30-day money back policy allows students to receive quality teaching services with minimal risk, we must also protect our teachers from fraud and provide them with a reasonable payment schedule. Payments are sent to instructors after 30 days, so we will not process refund requests received after the refund period.

We reserve the right, in our sole discretion, to limit or deny refund requests in cases where we believe there is refund abuse, including but not limited to the following:

  • A significant portion of the course has been consumed or downloaded by a student before the refund was requested.
  • Multiple refunds have been requested by a student for the same course.
  • Excessive refunds have been requested by a student.
  • Users whose account is blocked or access to courses is disabled due to violation of our Terms and Conditions or the Rules of Trust and Security.
  • We do not grant refunds for any subscription services.
  • These refund restrictions will be enforced to the extent permitted by applicable law.

We accept most international credit and debit cards like Visa, MasterCard, American Express, JCB and Discover. Bank Transfers also may be an option.

Smart Virtual Classroom (open digital / virtual classroom).

Conducting classes is based on the fact that the teacher demonstrates text, drawings, graphics, presentations on an interactive board, while the content appears in the student's electronic notebook. A specially designed digital notepad and pen are used to create and edit text and images that can be redirected to any surface via a projector.

Classes are live streamed online, automatically recorded and published on the Learning Portal, allowing you to save them for reuse anytime, anywhere, on any mobile device. This makes it possible not to miss classes and keep up with classes and keep up with the passage of new material.

Game Based Learning (learning using a virtual game environment)

Real-life training uses the principles of game organization, which allows future professionals to rehearse and hone their skills in a virtual emergency. Learning as a game provides an opportunity to establish a connection between the learning activity and real life.

The technology provides the following learning opportunities:

  • Focused on the needs of the user
  • Instant feedback
  • Independent decision making and choice of actions
  • Better assimilation and memorization of the material
  • Adaptive pace of learning tailored to the individual needs of the student
  • Better transfer of skills learned in a learning situation to real conditions

Basic principles of training:

  • A gradual increase in the level of difficulty in the game;
  • Using a simplified version of a problem situation;
  • Action in a variable gaming environment;
  • The right choice is made through experimentation.

The main advantages of Game Based Learning technology:

  • Low degree of physical risk and liability
  • Motivation to learn while receiving positive emotions from the process;
  • Practice - mirroring the real situation
  • Timely feedback
  • Choice of different playing roles
  • Learning in collaboration
  • Developing your own behavior strategy
Laboratory workshops using remote access technologies

Conducting practical classes online using remote access technologies for presentations, multimedia solutions and virtual reality:

  • Laboratory workshops that simulate the operation of expensive bench equipment in real production
  • Virtual experiment, which is visually indistinguishable from a remote real experiment performed
  • Virtual instruments, which are an exact copy of real instruments
  • Mathematical modeling to clarify the physical characteristics, chemical content of the investigated object or phenomenon.
GEOP007 - Analysis of Structural Traps in Extensional Settings
Language: English, Russian
Level: Intermediate
mail@tecedu.org
+7 747 898 5041
+7 7182 901 933