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Course Overview
This page focuses on the course 8.821 String Theory and Holographic Duality as it was taught by Professor Hong Liu in Fall 2014.
During the last fifteen years, string theory has revealed a surprising and deep connection between gravity and many-body physics under the name of holographic duality. The duality brings together many previously seemingly unconnected subjects including quantum gravity/black holes, QCD at extreme conditions, exotic condensed matter systems, and quantum information in an extremely elegant yet still mysterious manner. It also opens up new powerful approaches for studying these subjects from completely different perspectives. This course brings students to the forefront of this exciting field.
Course Outcomes
Course Goals for Students
- Understand that holographic duality is a rapidly developing field
- Gain an introduction to holography and general aspects of duality
- Learn about holographic renormalization group flows
- Gain insight into many-body systems
- Learn what questions in the area of quantum gravity are still outstanding
- Apply understanding of holographic duality in problem solving
Possibilities for Further Study/Careers
This course prepares students to complete doctoral thesis research.
Curriculum Information
Prerequisites
Requirements Satisfied
8.821 String Theory and Holographic Duality can be applied toward a doctoral degree in Physics.
Offered
On a variable schedule
Instructor Insights
I found it very rewarding to introduce students to holographic duality because it’s a field that is still rapidly developing.
—Hong Liu
Below, Professor Hong Liu describes various aspects of how he taught 8.821 String Theory and Holographic Duality in Fall 2014.
I found it very rewarding to introduce students to holographic duality because it’s a field that is still rapidly developing. It was exciting to bring students to the forefront of this active research arena. I think students found it to be an enriching experience, as well.
One challenge I faced in teaching the course was organizing the materials in an effective way. I addressed this challenge by identifying the most essential concepts and techniques students would need to know in order to being doing research in this area and organized the course around those topics.
Course Team Roles
Main Instructor
- Planned and delivered lectures
- Responded to student questions during lectures
Teaching Assistant
- Provided solutions to and graded students’ problem sets
The Classroom
Room 1 of 1 
Lecture
Lectures were held in a classroom with a seating capacity of 40 and moveable furniture.
Assessment
The students' grades were based on the following activities:
75% Problem Sets
25% Final ProjectInstructor Insights on Assessment
I do not give exams in 8.821 String Theory and Holographic Duality. Rather, I strongly encourage students to ask questions during our class sessions and these questions help me gauge how well they understand the material.
Student Information
Breakdown by Year
80% Graduate Students, 20% Seniors
Breakdown by Major
Mostly Physics
Typical Student Background
Typically, students have taken classes in Quantum Field Theories and General Relativity. Many tend to be theoretically-minded.
During an average week, students were expected to spend 12 hours on the course, roughly divided as follows:
Lecture
Met 2 times per week for 1.5 hours per session; 27 sessions total.
Out of Class
Out of class, students completed problems sets and worked on their final projects.
Semester Breakdown
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No classes throughout MIT Lecture session Student Presentations
No class session scheduled
Assignment due date