**Lectures:** Tuesday and Thursday 9:30-11, room 2-132

**Instructor:** Thomas Lam, room 2-169,
tfylam@mit.edu

**Course description:**
This is an introductory course in Schubert calculus, a branch of enumerative geometry with deep connections to combinatorics and
representation theory. A typical problem in Schubert calculus is: fix four lines in three-dimensional space; how many other lines
intersect all four?
Some of the topics we may study include: cohomology of Grassmannians and flag varieties, Schur functions, Schubert polynomials,
Littlewood-Richardson rules, equivariant Schubert calculus, K-theory Schubert calculus, affine Schubert calculus, quantum Schubert calculus,
back stable Schubert calculus

Familiarity with linear algebra is essential. Some experience with algebraic geometry and algebraic topology is helpful.

**Exams:**
There will be no exams.

**Homework:**
There will be four to five problem sets. Homework solutions should be typed in LaTeX and submitted at the beginning of class.
Late homework grades are penalized 20% per late day.

At the front of your homework solution, please acknowledge any books, online sources, etc. consulted, and indicate other
students you worked with on the homework.

**References:**

*Cohomology of Grassmannians and flag varieties:*

W. Fulton, Young tableaux, Cambridge University Press, 1997.

L. Manivel, Symmetric functions, Schubert polynomials and degeneracy loci, AMS, 2001.

*Equivariant cohomology of Grassmannians:*

Knutson and Tao, Puzzles and (equivariant) cohomology of Grassmannians.

Goresky, Kottwitz, and Macpherson, Equivariant cohomology, Koszul duality, and the localization theorem.

Tymoczko, An introduction to equivariant cohomology and homology, following Goresky, Kottwitz, and Macpherson

Anderson, Introduction to Equivariant Cohomology in Algebraic Geometry

**List of lectures:**

A previous version of this class is here.