1.2 Free Abelian Group

In this section, we write abelian group additively.

Definition

Let $F$ be an abelian group. For a subset $X \subseteq F$ , define $⟨ X ⟩ = {n_{1} x_{1} + \dots + n_{t} x_{t} : n_{i} \in Z, x_{i} \in X}$ . We say $X$ is a basis if

$⟨ X ⟩ = F$ , and

if $\sum_{i = 1}^{t} n_{i} x_{i} = 0$ for some $n_{i} \in Z$ and $x_{i} \in X$ , then $n_{i} = 0$ for all $i$ .

We say $F$ is a free abelian group if it has a basis.

Definition

Let ${G_{i}}_{i \in I}$ be a family of groups. Define

(external) direct product as $Π_{i \in I} G_{i} := {(a_{i})_{i \in I} : a_{i} \in G_{i}}$ .

(external) weak direct product as $Π_{i \in I}^{'} G_{i} := {(a_{i})_{i \in I} : a_{i} \in G_{i}, a_{i} = 1 \mbox f or a l m os t a ll i}$

Suppose $G_{i}$ are additive abelian groups, define (external) direct sum as $\oplus_{i \in I} G_{i} := Π_{i \in I}^{'} G_{i}$ .

Remark. The definition of (iii) is different from Hungerford.

Definition

Let ${N_{i} : i \in I}$ where $N_{i} ⊲ G$ . If

$⟨ \cup_{i \in I} N_{i} ⟩ = G$ , and

$\forall k \in I$ , $N_{k} \cap ⟨ \cup_{i \neq = k} N_{i} ⟩ = {e_{G}}$ ,

then we say $G$ is the internal weak direct product of $N_{i}$ , or internal direct sum of $N_{i}$ (if written additively). Conversely, $G ≃ Π_{i \in I}^{'} N_{i}$ .

Theorem

Let $F$ be an abelian group. TFAE:

$F$ has a non-empty basis $X$ .

$F$ is the (internal) direct sum of a family of infinite cyclic groups.

$F ≃ \oplus_{i \in I} Z$ is an (external) direct sum of copies of $(Z, +)$ .

\begin{proof} i) → ii). For any $x \in X$ , $n x = 0$ iff $n = 0$ . Thus $⟨ x ⟩$ is an infinite cyclic subgroup. Claim: $F$ is the internal direct sum of $⟨ x ⟩$ for all $x \in X$ . By definition, it suffices to check that $⟨ x ⟩ \cap ⟨ X ∖ {x} ⟩ = {0}$ . Indeed, if $n x = \sum_{x_{i} \neq = x} n_{i} x_{i}$ , then $n = 0$ and $n_{i} = 0$ . So we finish the proof.

ii) → iii). Easy.

iii) → i). Easy. \end{proof}

Theorem

Let $F$ be a finite generated abelian group. Then any two bases of $F$ have the same cardinality.

\begin{proof} By ^2408e8, suppose $F ≃ \oplus_{i \in I} Z$ and $F ≃ \oplus_{j \in J} Z$ . Then $F /2 F ≃ \oplus_{i \in I} Z /2 Z$ and $F /2 F ≃ \oplus_{j \in J} Z /2 Z$ . Then $∣ F /2 F ∣ = 2^{∣ I ∣} = 2^{∣ J ∣}$ . Thus $∣ I ∣ = ∣ J ∣$ . \end{proof}

Definition

The rank of finite generated abelian group $F$ is the cardinality of basis, denoted by $rk F$ or $rk_{Z} F$ .

Corollary

Let $F_{1}, F_{2}$ be two finite generated abelian group. Then $F_{1} ≃ F_{2}$ iff $rk F_{1} = rk F_{2}$ .

Theorem

Let $G$ be an abelian group. Then it is the homomorphic image of a free abelian group of rank $∣ X ∣$ , where $X$ is a set of generators of $G$ .

\begin{proof} Let $F := \oplus_{x \in X} Z$ . Define $f : F \to G, (n_{x} x)_{x \in X} \mapsto \sum_{x \in X} n_{x} x$ . Then $G = Im f$ . \end{proof}

Theorem

Let $M$ be a finite generated free abelian group with $rk_{Z} M = n$ . Let $M^{'} < M$ nonzero. Then

$M^{'}$ is also a free abelian group with $rk M^{'} = q ⩽ n$ .

There exists some basis $(e_{1}, \dots, e_{n})$ of $M$ and $a_{1}, \dots, a_{q} \in Z^{+}$ such that $a_{1} ∣ a_{2} ∣ \dots ∣ a_{q}$ such that $(a_{1} e_{1}, \dots, a_{q} e_{q})$ is a basis of $M^{'}$ .

Before the proof, we firstly give the following examples.

Examples.

$M = Z$ and $M^{'} = 2 Z$ . Then $e_{1} = 1$ and $a_{1} = 2$ .
$M = Z e_{1} \oplus Z e_{2}$ and $M^{'} = ⟨ 2 e_{1} + 3 e_{2} ⟩$ . If we let $f_{1} = 2 e_{1} + 3 e_{2}$ and $f_{2} = e_{1} + 2 e_{2}$ , then $(f_{1}, f_{2})$ is a basis of $M$ and $1 \cdot f_{1}$ is a basis of $M^{'}$ with $a_{1} = 1$ .
$M = Z e_{1} \oplus Z e_{2}$ and $M^{'} = ⟨ 3 e_{1}, 4 e_{2} ⟩$ . Let $f_{1} = 3 e_{1} + 4 e_{2}$ and $f_{2} = 2 e_{1} + 3 e_{2}$ . Then $M^{'} = ⟨ f_{1}, 12 f_{2} ⟩$ .

How to compute $a_{1}, \dots, a_{q}$ ?

Let $M = Z e_{1} \oplus Z e_{2}$ and $M^{'} = ⟨ 2 e_{1} + 3 e_{2}, 4 e_{1} + 12 e_{2} ⟩$ . $M^{'}$ can be written as $[24312] [e_{1} e_{2}]$ . Note that
$= = = [24312] [e_{1} e_{2}] [1201] [2036] [e_{1} e_{2}] [1201] [1601] [0110] [- 12 0 01] [1213] [e_{1} e_{2}] M [- 12 0 01] [e_{1} + e_{2} 2 e_{1} + 3 e_{2}] .$
where $M$ is a invertible matrix. So $M^{'} = ⟨ f_{1}, 12 f_{2} ⟩$ where $f_{1} = 2 e_{1} + 3 e_{2}$ and $f_{2} = e_{1} + e_{2}$ .

Now we prove ^93020f and we start with a lemma.

Lemma

Let $f : M \to N$ be an epimorphism of abelian groups, and suppose $N$ is a finite generated free abelian group. Then $M ≃ N \oplus ker f$ as abelian groups.

\begin{proof} Let ${e_{1}, \dots, e_{n}}$ be a basis of $N$ . Suppose $x_{i} \in M$ such that $f (x_{i}) = e_{i}$ . Define a map $g : M \to N \oplus ker f$ where for $x \in M$ , suppose $f (x) = \sum_{i = 1}^{n} a_{i} e_{i}$ , $a_{i} \in Z$ , then let $g (x) = (f (x), x - \sum_{i = 1}^{n} a_{i} x_{i}) \in N \oplus ker f$ . Then it suffices to check $g$ is an isomorphism.

Homomorphism: It is easy to verify $g$ is a homomorphism.
Injective: If $f (x) = x - \sum_{i = 1}^{n} a_{i} x_{i} = 0$ , then $\sum a_{i} e_{i} = 0$ , $a_{i} \equiv 0$ and so $x = 0$ . Thus $g$ is injective.
Surjective: Given $(α, β) \in N \oplus ker f$ , then $α = \sum_{i = 1}^{n} a_{i} e_{i}$ . Let $x = \sum_{i = 1}^{n} a_{i} x_{i} + β \in M$ . Then $g (x) = (α, β)$ . \end{proof}

Remark. $0 \to ker f \to M \to f N \to 0$ is a short exact sequence. If $N$ is free, then there exists $s : N \to M$ such that $f \circ s = id_{N}$ .

\begin{proof} It is a proof of ^93020f, (i).

(i) By induction on $n$ . When $n = 1$ , then $M = Z e > M^{'} \neq = 0$ . Elements in $M$ are of form $a e$ for some $a \in Z$ . Let $a_{1} = min {a \in Z : a e \in M^{'}}$ . Claim that $M^{'} = ⟨ a_{1} e ⟩$ . Indeed, $⟨ a_{1} e ⟩ \subseteq M^{'}$ . If it is not equal, then there exists $a e \in M^{'}$ and $a e \in / ⟨ a_{1} e ⟩$ . WLOG $a > 0$ . Since $a e \in / ⟨ a_{1} e ⟩$ , we have that $a_{1} \neq ∣ a$ and $(a_{1}, a) = b < a_{1}$ . Then by Bezout’s theorem there exists $x, y \in Z$ such that $a x + a_{1} y = b$ , and so $x (a e) + y (a_{1} e) = b e \in M^{'}$ . But $0 < b < a_{1}$ , which contradicts with minimality of $a_{1}$ .

Now suppose (i) holds when $rk M ⩽ n$ . Now consider $π : M = Z \oplus Z^{n} ↠ Z^{n}, (a, b) \mapsto b$ . Let $N = π (M^{'}) < Z^{n}$ . By induction hypothesis, $N$ is free with $rk N ⩽ n$ . Also we know $π$ induces a map $π ∣_{M^{'}} : M^{'} ↠ N$ . By ^f38221, $M^{'} ≃ N \oplus ker (π ∣_{M}^{'})$ . Note that $ker π = Z \oplus 0$ . Thus $ker (π ∣_{M^{'}}) < Z \oplus 0$ is free, whose rank is less equal than $1$ . Therefore, $M^{'}$ is free and $rk ⩽ n + 1$ .

(ii) When $n = 1$ , the statement is trivial (see (i)). Consider the case of $n = 2$ . By ^f38221, $M^{'}$ can be decomposed a s $M^{'} = π (M^{'}) \oplus ker π ∣_{M^{'}}$ where $π (M^{'}) ⩽ Z$ and $ker π ∣_{M^{'}} ⩽ Z \oplus 0$ . By case of $n = 1$ , we get $M^{'} = a_{1} f_{1}^{'} \oplus a_{2} f_{2}^{'}$ for some basis $f_{1}^{'}, f_{2}^{'}$ and $a_{1}, a_{2} ⩾ 0$ . If one of $a_{i} = 0$ , we have done. So suppose $a_{i} \neq = 0$ , $i = 1, 2$ . (naive idea: hope $a_{1} ∣ a_{2}$ , i.e. want $a_{1}$ to be “small”.) Consider the set

P = {a \in Z_{⩾ 0} : \exists b \in Z_{⩾ 0}, \mbox an d t h eree x i s t s aba s i s (f_{1}^{''}, f_{2}^{''}) \mbox o f M \mbox s u c h t ha t M^{'} = ⟨ a f_{1}^{''}, b f_{2}^{''} ⟩} .

Since $a_{1} \in P$ and $P$ is non-empty, then there exists unique element $α \in P$ . So $M^{'} = ⟨ α f_{1}, β f_{2} ⟩$ . Now claim that $α ∣ β$ . Otherwise, $(α, β) = t < α$ . Write $α = t x_{1}$ and $β = t x_{2}$ and let $t = α y_{1} + β y_{2}$ . Then $x_{1} y_{1} + x_{2} y_{2} = 1$ . Note that $M^{'} = ⟨ α f_{1}, β f_{2} ⟩ = ⟨ t (x_{1} f_{1} + x_{2} f_{2}), t x_{1} x_{2} (- y_{2} f_{1} + y_{1} f_{2}) ⟩$ by $det [1 - x_{2} y_{2} 1 x_{1} y_{1}] = 1$ . In addition, $(x_{1} f_{1} + x_{2} f_{2}, - y_{2} f_{1} + y_{1} f_{2}) = (f_{1}, f_{2}) [x_{1} x_{2} - y_{2} y_{1}]$ and $det [x_{1} x_{2} - y_{2} y_{1}] = 1$ yield that $(x_{1} f_{1} + x_{2} f_{2}, - y_{2} f_{1} + y_{1} f_{2})$ is a basis. Thus $t \in P$ , which contradicts with minimality of $α$ . So $α ∣ β$ . Now we finish the proof of the case $n = 2$ . (For example, let $M^{'} = ⟨ 10 e_{1}, 15 e_{2} ⟩ < ⟨ e_{1}, e_{2} ⟩$ . Use above algorithm, $(α, β) = (10, 15) = 5 = t$ . Then $x_{1} = 2, x_{2} = 3$ and $y_{1} = - 1, y_{2} = 1$ . It yields that $M^{'} = ⟨ 5 (2 e_{1} + 3 e_{2}), 30 (- e_{1} - e_{2}) ⟩$ . )

Now suppose that the statement is true for $n$ -case. now suppose $M = Z^{n + 1}$ . Again, $M^{'} = ker ∣_{M^{'}} \oplus π (M^{'})$ where $π (M) ⩽ Z^{n}$ and $ker ∣_{M^{'}} ⩽ Z \oplus 0$ . By induction hypothesis, $π (M^{'}) = ⟨ a_{1} f_{1}, a_{2} f_{2}, \dots, a_{n + 1} f_{n + 1} ⟩$ where $a_{2} ∣ a_{3} ∣ \dots ∣ a_{n + 1}$ . Let

P = {a \in Z_{+} : \exists b_{2} ∣ b_{3} ∣ \dots ∣ b_{n + 1} \mbox an d \exists (f_{1}, \dots, f_{n + 1}) \mbox s u c h t ha t M^{'} = ⟨ a_{1} f_{1}, \dots, a_{n + 1} f_{n + 1} ⟩} .

Since $a_{1} \in P$ , $P$ is non-empty. Then let $α$ be the minimal element of $P$ . Claim that $α ∣ b_{2}$ . We start with checking $α ∣ β_{n + 1}$ . Otherwise, $(α, β_{n + 1}) = t < α$ and we can use the trick in the case of $n = 2$ . Note that $M^{'} = ⟨ t (x_{1} f_{1} + x_{2} f_{n + 1}, β_{2} f_{2}, \dots, β_{n} f_{n}, t x_{1} x_{2} (- y_{2} f_{1} + y f_{n + 1})) ⟩$ and so $t \in P$ , contradiction. Next, we check $α ∣ β_{n}$ . If not, then similar to above we can change the sequence $α, β_{2}, \dots, β_{n - 1}, β_{n}, β_{n + 1}$ to $t, β_{2}, \dots, β_{n - 1}, t x_{1} x_{2}, β_{n + 1}$ , where $α = t x_{1}$ and $β_{n} = t x_{2}$ . Claim that $t x_{1} x_{2} ∣ β_{n + 1}$ . Indeed, since $t x_{1} ∣ β_{n + 1}$ and $t x_{2} ∣ β_{n + 1}$ , we have $[t x_{1}, t x_{2}] ∣ β_{n + 1}$ with $[t x_{1}, t x_{2}] = t x_{1} x_{2}$ . Therefore, $t \in P$ , which is impossible. So $α ∣ β_{n}$ . Repeat the procedure, we can prove that $α ∣ β_{1}$ and so we finish the proof. \end{proof}

Corollary

Let $G$ be a finitely generated abelian group, which is generated by $n$ elements. Then any $H < G$ can be generated by $m$ elements with $m ⩽ n$ .

\begin{proof} By ^d4cf25, there exists free abelian group $F$ of rank $n$ giving rise to an epimorphism $π : F \to G$ . Since $π^{- 1} (H) < F$ , by ^93020f $π^{- 1} (H)$ is free, whose rank is less equal than $n$ . As $π^{- 1} (H) ↠ H$ , the image of a basis of $π^{- 1} (H)$ gives a set of generators of $H$ . \end{proof}

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1.2 Free Abelian Group

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