Algebraic Geometry

🌿Algebraic Geometry Unit 1 – Introduction to Algebraic Geometry

Algebraic geometry bridges algebra and geometry, studying geometric objects defined by polynomial equations. It explores affine and projective varieties, coordinate rings, and morphisms between varieties. This field has roots in ancient mathematics but was formalized in the 20th century. Modern algebraic geometry introduces powerful tools like sheaves and schemes to study varieties and their properties. It has applications in number theory, complex analysis, physics, and cryptography. The interplay between algebraic and geometric perspectives is central to this rich and challenging field.

Study Guides for Unit 1

1.1

Affine varieties and polynomial rings

7 min read

1.2

Projective varieties and homogeneous coordinates

5 min read

1.3

Morphisms and rational maps

6 min read

1.4

Dimension and degree of varieties

4 min read

Key Concepts and Definitions

Algebraic geometry studies geometric objects defined by polynomial equations and the properties of these objects that are invariant under algebraic transformations
Affine varieties are defined as the zero locus of a set of polynomials in affine space $\mathbb{A}^n$
Projective varieties are defined as the zero locus of a set of homogeneous polynomials in projective space $\mathbb{P}^n$ $P^{n}$
- Homogeneous polynomials have the same degree for each monomial term
Coordinate rings are the rings of regular functions on an affine variety
- Regular functions are polynomial functions that are well-defined on the variety
Morphisms between varieties are maps that preserve the algebraic structure
- They can be described by polynomial functions between the coordinate rings
Sheaves are a tool for studying local properties of varieties
- They assign algebraic data (rings, modules) to open sets of a variety
Schemes are a generalization of varieties that allow for more general "geometric" objects
- They are defined by gluing together affine schemes (spectra of rings)

Historical Context and Importance

Algebraic geometry has its roots in the study of polynomial equations and their solutions (roots) dating back to ancient civilizations (Babylonians, Greeks)
In the 19th century, mathematicians (Riemann, Dedekind, Hilbert) began to study geometric objects defined by polynomial equations more abstractly
The modern foundations of algebraic geometry were laid in the 20th century by mathematicians such as Emmy Noether, André Weil, and Alexander Grothendieck
- They introduced powerful algebraic tools (rings, modules, categories) to study varieties and their properties
Algebraic geometry has important applications in various fields:
- Number theory (studying solutions to equations over different number fields)
- Complex analysis (studying complex manifolds and their algebraic properties)
- Physics (string theory, mirror symmetry)
- Cryptography (elliptic curve cryptography)
The interplay between algebra and geometry is a central theme in modern mathematics, with algebraic geometry serving as a bridge between the two subjects

Affine Varieties and Coordinate Rings

Affine n-space over a field $k$ , denoted $\mathbb{A}^n(k)$ , is the set of all n-tuples of elements from $k$
An affine variety $V$ $V$ is the zero locus of a set of polynomials $f_1,\ldots,f_m \in k[x_1,\ldots,x_n]$ $f_{1}, \dots, f_{m} \in k [x_{1}, \dots, x_{n}]$ :
- $V = V(f_1,\ldots,f_m) = \{(a_1,\ldots,a_n) \in \mathbb{A}^n(k) : f_i(a_1,\ldots,a_n)=0 \text{ for all } i\}$
The coordinate ring of an affine variety $V$ $V$ , denoted $k[V]$ $k [V]$ , is the quotient ring $k[x_1,\ldots,x_n]/I(V)$ $k [x_{1}, \dots, x_{n}] / I (V)$
- $I(V)$ is the ideal of all polynomials that vanish on $V$
The Nullstellensatz states that there is a bijective correspondence between affine varieties and radical ideals in $k[x_1,\ldots,x_n]$ $k [x_{1}, \dots, x_{n}]$
- This allows for studying geometric properties of varieties using algebraic properties of their coordinate rings
Examples of affine varieties include:
- Curves (elliptic curves, hyperelliptic curves)
- Surfaces (quadric surfaces, cubic surfaces)
- Hypersurfaces (defined by a single polynomial equation)

Projective Spaces and Projective Varieties

Projective n-space over a field $k$ , denoted $\mathbb{P}^n(k)$ , is the set of equivalence classes of $(n+1)$ -tuples $(a_0,\ldots,a_n) \in k^{n+1} \setminus \{(0,\ldots,0)\}$ under the equivalence relation $(a_0,\ldots,a_n) \sim (\lambda a_0,\ldots,\lambda a_n)$ for all $\lambda \in k^\times$
A projective variety $V$ $V$ is the zero locus of a set of homogeneous polynomials $f_1,\ldots,f_m \in k[x_0,\ldots,x_n]$ $f_{1}, \dots, f_{m} \in k [x_{0}, \dots, x_{n}]$ :
- $V = V(f_1,\ldots,f_m) = \{[a_0:\ldots:a_n] \in \mathbb{P}^n(k) : f_i(a_0,\ldots,a_n)=0 \text{ for all } i\}$
Projective varieties can be studied using homogeneous coordinate rings, which are graded rings generated by the homogeneous polynomials vanishing on the variety
Projective varieties have important geometric properties:
- They are compact (in the Zariski topology)
- They have a well-defined intersection theory (Bézout's theorem)
Examples of projective varieties include:
- Projective spaces themselves
- Projective curves (elliptic curves, plane curves)
- Projective hypersurfaces (defined by a single homogeneous polynomial equation)

Morphisms and Regular Functions

A morphism between two affine varieties $V \subseteq \mathbb{A}^n$ $V \subseteq A^{n}$ and $W \subseteq \mathbb{A}^m$ $W \subseteq A^{m}$ is a map $\varphi: V \to W$ $φ : V \to W$ that can be described by polynomial functions $\varphi_1,\ldots,\varphi_m \in k[x_1,\ldots,x_n]$ $φ_{1}, \dots, φ_{m} \in k [x_{1}, \dots, x_{n}]$ :
- $\varphi(a_1,\ldots,a_n) = (\varphi_1(a_1,\ldots,a_n),\ldots,\varphi_m(a_1,\ldots,a_n))$
A regular function on an affine variety $V$ $V$ is a function $f: V \to k$ $f : V \to k$ that can be described by a polynomial in $k[x_1,\ldots,x_n]$ $k [x_{1}, \dots, x_{n}]$
- The set of all regular functions on $V$ forms the coordinate ring $k[V]$
Morphisms between projective varieties can be described using homogeneous polynomials
- They must preserve the equivalence relation defining projective space
Isomorphisms are morphisms with an inverse morphism
- Isomorphic varieties have the same geometric and algebraic properties
Examples of morphisms include:
- Inclusion maps (closed immersions)
- Projection maps
- Birational maps (rational functions that are invertible on a dense open set)

Sheaves and Schemes (Intro)

Sheaves are a tool for studying local properties of varieties
- They assign algebraic data (rings, modules) to open sets of a variety in a way that is compatible with restriction
The structure sheaf $\mathcal{O}_V$ $O_{V}$ of a variety $V$ $V$ assigns to each open set $U \subseteq V$ $U \subseteq V$ the ring of regular functions on $U$ $U$
- This allows for studying local properties of functions on $V$
Schemes are a generalization of varieties that allow for more general "geometric" objects
- They are defined by gluing together affine schemes (spectra of rings) along open subsets
Affine schemes are the building blocks of schemes
- The affine scheme $\operatorname{Spec}(R)$ of a ring $R$ is the set of prime ideals of $R$ with a topology (Zariski topology) and a structure sheaf
Morphisms between schemes are defined locally by morphisms between their affine patches
- This allows for studying more general geometric objects (singular varieties, arithmetic schemes) using the same tools as for varieties

Applications and Examples

Algebraic geometry has important applications in various fields:
- In number theory, algebraic varieties over finite fields or number fields are used to study Diophantine equations and their solutions
  - Examples include elliptic curves and their use in cryptography (elliptic curve cryptography)
- In complex analysis, complex algebraic varieties are studied as complex manifolds with additional algebraic structure
  - This leads to important results in Hodge theory and the study of Kähler manifolds
- In physics, algebraic geometry is used in string theory and the study of mirror symmetry
  - Calabi-Yau manifolds and their moduli spaces play a central role in these applications
Some famous examples of algebraic varieties include:
- Fermat curves: $x^n + y^n = 1$ (for various values of $n$ )
- Elliptic curves: $y^2 = x^3 + ax + b$ (with $4a^3 + 27b^2 \neq 0$ )
- Grassmannians: varieties parametrizing subspaces of a fixed dimension in a vector space
- Flag varieties: varieties parametrizing chains of subspaces of a vector space

Common Challenges and Tips

Algebraic geometry can be abstract and challenging to learn at first, as it requires a solid foundation in algebra (rings, modules, categories) and geometry (topology, manifolds)
- It's important to have a good grasp of linear algebra, abstract algebra, and topology before diving into algebraic geometry
The language and notation used in algebraic geometry can be intimidating and difficult to parse
- It's helpful to keep a list of key definitions and theorems handy and to practice translating between the algebraic and geometric perspectives
Visualizing algebraic varieties can be challenging, especially in higher dimensions
- It's useful to work out explicit examples in low dimensions (curves, surfaces) and to use computational tools (such as Macaulay2 or Sage) to explore varieties
Proofs in algebraic geometry often involve intricate algebraic manipulations and geometric intuition
- It's important to break down proofs into smaller steps and to try to understand the geometric motivation behind each step
Some key techniques and tools to master in algebraic geometry include:
- Working with ideals and quotient rings
- Computing Gröbner bases and using elimination theory
- Understanding the correspondence between varieties and ideals (Nullstellensatz)
- Working with sheaves and understanding their cohomology
- Using spectral sequences and other homological algebra tools