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189-571B: Higher Algebra II
Assignment 3. Due: Monday, March 11.
This assignment is meant to help you study for the midterm exam which is scheduled on March 13. The Monday deadline will allow us to discuss any questions you
might have about it, ahead of the midterm exam.
1. Let $V\subset {\mathbb A}^n$ be a variety over a field $k$,
corresponding to an ideal $I$ of $k[x_1,\ldots,x_n]$.
Show that the maximal ideals of $k[x_1,\ldots, x_n]$ containing $I$
are in natural bijection with the Galois orbits of points over
the algebraic closure. (The absolute Galois group of $k$ acts naturally and
continuously on $V(\bar k)$, and a Galois orbit is just a -necessarily finite-
orbit for this action.)
2. Explain whether the following assertions are true or false.
Here $\bar k$ denotes the algebraic closure of a field $k$.
(a) If $I$ is a maximal ideal of $k[x_1,\ldots, x_n]$, then it generates a maximal ideal of $\bar k[x_1,\ldots, x_n]$.
(b) If $I$ is a prime ideal of $k[x_1,\ldots, x_n]$, then it generates a prime
ideal of $\bar k[x_1,\ldots, x_n]$.
(c) If $I$ is a maximal ideal of $k[x_1,\ldots, x_n]$, then the
ideal of $\bar k[x_1,\ldots, x_n]$ that is generated by $I$ is the intersection of finitely many maximal ideals of $\bar k[x_1,\ldots,x_n]$.
3.
Keep the
notations as in the previous question, but assume further that $k$ is algebraically closed.
Show that the prime ideals containing $I$ are in natural bijection with the
irreducible subvarieties of $V$,
and that the minimal prime ideals containing $I$ are
in bijection with the irreducible components of $V$.
4.
Show that the radical of an ideal $I$ of
$k[x_1,\ldots, x_n]$
is equal to the intersection of the prime ideals
containing $I$.
5. Let $k$ be an algebraically closed field.
Let $V$ be an affine variety in ${\mathbb A}^n$ attached to
an ideal $I$ of $k[x_1,\ldots, x_n]$, and let
let $\bar V$ denote its
projective closure in ${\mathbb P}_n$, obtained by
homogenising the collection of equations defining $V$ to obtain a homogenous
ideal of $k[x_0,\ldots,x_n]$.
Show that $V \mapsto \bar V$ defines a bijection between the non-empty affine
varieties in ${\mathbb A}^n$ and the non-empty projective varieties in
${\mathbb P}_n$ none of whose irreducible components lie on the
``hyperplane at infinity"
$$ {\mathbb P}_{n-1}^{(\infty)} := \{ (x_0:x_1:\cdots : x_n) \mbox{ such that }
x_0=0 \}.$$
6. With notations as in question 5, show that if
$V=V_1\cup\cdots \cup V_s$ is the decomposition of $V$ as a union of its
irreducible components, then $\bar V = \bar V_1 \cup \cdots \cup \bar V_s$
is the decomposition of $\bar V$ as a union of its irreducible components.
7.
Kunz, Exercise 2, page 29.
8.
Kunz, Exercise 4, page 29.
9.
Kunz, Exercise 4, page 37.
10.
Kunz, Exercise 6, page 38.