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2017/18 Taught Postgraduate Module Catalogue
MATH5253M Commutative Algebra and Algebraic Geometry
20 creditsClass Size: 30
Module manager: Dr Eleonore Faber
Taught: Semester 2 (Jan to Jun) View Timetable
Year running 2017/18
Pre-requisite qualificationsMATH3193 or equivalent.
This module is approved as an Elective
Module summaryAlgebraic geometry is the study of spaces defined as the solution sets of polynomials in several indeterminates. It plays an ever more important role in mathematics, for example in elliptic curve cryptography and in Wiles' proof of Fermat's Last Theorem (although these topics aren't included in the module). One of the reasons why algebraic geometry is so useful is that one can use powerful abstract results about commutative rings. At the heart of this module are two of the most famous of these results, Hilbert's Basis Theorem and Nullstellensatz (Zeros Theorem).
ObjectivesTo introduce the student to the basic ideas of algebraic geometry, the associated commutative algebra, and the interplay between the ideas of algebra and geometry.
On completion of this module, students should be able to:
a) Define some of the main concepts in commutative algebra and algebraic geometry.
b) State and prove some of the basic results in commutative algebra and algebraic geometry.
c) Use Hilbert's Basis Theorem and other techniques to show that certain examples of modules and ideals are finitely generated.
d) Find the radical of a given ideal in simple cases, and hence find the ideals of varieties defined by simple equations.
e) Decompose simple examples of varieties into unions of irreducible components.
Commutative rings. Prime and maximal ideals. Finitely generated modules. Hilbert's Basis Theorem. Integral extensions. The correspondence between ideals in the polynomial ring and algebraic sets in affine space. Hilbert's Nullstellensatz. Irreducible decomposition. Further topics.
1. Reminder about commutative rings, ideals and factor rings. Polynomial rings in several indeterminates over a field, and rings which are finitely generated over a field. Zorn's Lemma. Prime ideals and maximal ideals. Localisation.
2. Modules. Isomorphism Theorems. Generators of a module. Free modules. Nakayama's Lemma. Noetherian rings and modules. Hilbert's Basis Theorem. Integral extensions. Noether normalization. The weak Nullstellensatz, that a field extension which is finitely generated as an algebra is algebraic. Tensor Products.
3. Affine varieties. The Zariski topology. The ideal of an affine variety. Radical ideals. The coordinate ring of an affine variety. Hilbert's Nullstellensatz, that the ideal of the affine variety defined by an ideal is the radical of that ideal. Correspondence between the points of an affine variety and the maximal ideals of its coordinate ring. Irreducible decomposition.
4. Topic(s) chosen from: projective varieties and Grassmannians; non-singular varieties and dimension; Bezout's Theorem and the group law for elliptic curves.
|Private study hours
|Total Contact hours
|Total hours (100hr per 10 credits)
Opportunities for Formative FeedbackRegular example sheets
Methods of assessment
|% of formal assessment
|Standard exam (closed essays, MCQs etc)
|3 hr 00 mins
|Total percentage (Assessment Exams)
Normally resits will be assessed by the same methodology as the first attempt, unless otherwise stated
Reading listThe reading list is available from the Library website
Last updated: 11/12/2017
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