Florian Herzig - Math 1101

MAT 1101: Algebra II, Winter 2026

Instructor: Florian Herzig; my last name at math dot toronto dot edu
Office Hours (online/zoom): Fri 3:30-4:30pm or by appointment

TA: Yun-chi Tang

Lectures: Tuesday/Thursday 10:30-12pm

Official syllabus

Fields: Algebraic and transcendental extensions, normal and separable extensions, fundamental theorem of Galois theory, solution of equations by radicals.
Commutative Rings: Noetherian rings, Hilbert basis theorem, invariant theory, Hilbert Nullstellensatz, primary decomposition, affine algebraic varieties.
Structure of semisimple algebras, application to representation theory of finite groups.

(We may not get to invariant theory and primary decomposition, for time reasons.)

Useful books for reference (I will not really follow any of them)

Grillet, Abstract algebra (click link for online access; this book might be the closest to my course)
Dummit and Foote, Abstract Algebra, 3rd ed.
Jacobson, Basic Algebra, Volumes I and II.
Lang, Algebra, 3rd ed.

For representation theory:

Serre, Linear representations of finite groups
Alperin and Bell, Groups and representations
Webb, A Course in Finite Group Representation Theory (available online)

Grading scheme

The grading scheme will be finalised during the first week of classes.

Homework: 0%

2 Term tests: 30% each

Final: 40%

Term tests (tentative dates): Tue Feb 3 and Tue Mar 10, during class time (10:30am-12:00pm). There will be no makeup tests! If you miss the test for a valid reason, the grade will be reweighted.
Final: TBA (April)

Homework

Assignments are optional, but you are strongly encouraged to work on them and hand them in for feedback. I will be using Gradescope (gradescope.ca, not gradescope.com!).

Assignment 1
Assignment 2
Assignment 3
Assignment 4
Assignment 5

Rough class schedule

Note that I will be absent during the week of February 9, since I will speak at a conference.

Jan 6: Galois theory: motivation, field extensions, degree, finite extensions, k-homomorphisms, algebraic and transcendental elements
Jan 8: tower law, universal property of the field $k_f = k[x]/(f(x))$ (over $k$), algebraic/finitely generated/simple extensions
Jan 13: algebraic closure (existence)
Jan 15:
Jan 20:
Jan 22:
Jan 27:
Jan 29:
Feb 3:
Feb 5:
Feb 10: (no class)
Feb 12: (no class)
Feb 17:
Feb 19:
Feb 24:
Feb 26:
Mar 3:
Mar 5:
Mar 10:
Mar 12:
Mar 17:
Mar 19:
Mar 24:
Mar 26:
Mar 31:
Apr 2: