Math 361, Spring 2015, Assignment 9
From cartan.math.umb.edu
Carefully define the following terms, then give one example and one non-example of each:[edit]
- Algebraically closed field.
- Algebraic closure.
- Compass-and-straightedge construction.
- Squaring the circle.
- Duplicating the cube.
- Trisection of angles.
- Constructible number.
Carefully state the following theorems (you do not need to prove them):[edit]
- Theorem giving various conditions characterizing algebraically closed fields.
- Theorem concerning existence and uniqueness of algebraic closures.
- Theorem relating constructible numbers to fields.
- Theorem concerning square roots of constructible numbers.
- Theorem characterizing constructible numbers in terms of towers of field extensions.
- Theorem concerning the degree of a constructible number over $\mathbb{Q}$.
Solve the following problems:[edit]
- Section 32, problems 1 and 10.
- (Objects algebraic over $\mathbb{Z}_p$) Suppose $p$ is prime, that $\mathbb{Z}_p\rightarrow E$ is a field extension, and that $\alpha\in E$ is algebraic over $\mathbb{Z}_p$. Show that the subextension $\mathbb{Z}_p(\alpha)$ has only finitely many elements. (One might say that anything algebraic over $\mathbb{Z}_p$ can be modelled inside a finite field; thus, when we have studied finite fields we will have gone a long way towards understanding the algebraic closure of $\mathbb{Z}_p$.)
- (Direct limit of a chain of fields) Suppose we have a tower of field extensions $$F_1\rightarrow F_2\rightarrow F_3\rightarrow\dots.$$ We will construct a new field which is in some sense the "union" of all the $F_i$, and which is called the direct limit of the $F_i$. Let $\Omega$ denote the subset of $\mathbb{Z}_{\geq0}\times\bigcup_i F_i$ consisting of all pairs of the form $(i,\alpha)$ with $\alpha\in F_i$. Define a relation $\simeq$ on $\Omega$ by declaring that $(i,\alpha) \simeq (j,\beta)$ if either $i\leq j$ and the image of $\alpha$ in $F_j$ equals $\beta$, or $j\leq i$ and the image of $\beta$ in $F_i$ equals $\alpha$. Show that $\simeq$ is an equivalence relation on $\Omega$, then define operations on $\Omega/\simeq$ that turn it into a field. (This construction can be generalized to non-linear "diagrams" of field extensions. The previous exercise then suggests rather strongly that the algebraic closure of $\mathbb{Z}_p$ can be constructed as the direct limit of all finite fields of characteristic $p$.)
