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Elements of a finite field as a sum of two squares or two cubes

Posted: February 6, 2019 in Elementary Algebra; Problems & Solutions, Groups and Fields
Tags: finite field, sum of cubes, sum of squares

It is well-known that, in a finite field, every element is a sum of two squares (Problem 1). It is however not true that every element of a finite field is a sum of two cubes. For example, in $\mathbb{Z}_7,$ we cannot write $3$ or $4$ as a sum of two cubes because $\{a^3: \ a \in \mathbb{Z}_7\}=\{0,1,6\}$ and so the only elements of $\mathbb{Z}_7$ that are a sum of two cubes are $0,1,2,5,6.$
But if, in a finite field, $\alpha^3=2$ for some non-zero element $\alpha$ of the field, then we can show that every element of the field is a sum of two cubes (Problem 2).

Problem 1. Show that every element of a finite field is a sum of two squares.

Solution. Let $F$ be a finite field. So we want to show that if $x \in F,$ then $x=a^2+b^2$ for some $a,b \in F.$ We can actually be more specific if we consider two cases. Let $|F|=q.$

Case 1: $q=2n$ for some integer $n.$ Then, since $x^q=x$ for all $x \in F,$ we get $x=(x^n)^2.$ So in this case, every element of the field is a square.

Case 2: $q=2n+1$ for some integer $n.$ Since $F$ is finite, the multiplicative group $F^{\times}$ is cyclic.
So $F^{\times}=\langle c \rangle.$ Let $x \in F$ and consider the sets

$A:=\{a^2: \ \ a \in F\}, \ \ \ B:=\{x-a^2: \ \ a \in F\}.$

Clearly $\{0\} \cup \{c^{2m}: \ \ 1 \le m \le n\} \subseteq A$ and $|A|=|B|.$ Thus $|A| \ge n+1$ and hence

$|A|+|B| =2|A| \ge 2n+2 > |F|.$

Therefore $A \cap B \neq \emptyset,$ i.e. there exist $a,b \in F$ such that $a^2=x-b^2$ and the result follows. $\Box$

Remark 1. Regarding the second case in the solution of Problem 1, notice that, in fact, we have

$A= \{0\} \cup \{c^{2m}: \ \ 1 \le m \le n\}$

and so $|A|=n+1.$ The reason is that if $c^k=c^{2m}$ for some integers $k,m,$ then $c^{k-2m}=1$ and hence $k-2m$ must be divisible by $|F^{\times}|=2n$ implying that $k$ is even.

Problem 2. Let $F$ be a finite field and suppose that there exists $0 \ne \alpha \in F$ such that $\alpha^3=2.$ Show that every element of $F$ is a sum of two cubes.

Solution. So we want to show that if $x \in F,$ then $x=a^3+b^3$ for some $a,b \in F.$ Let $|F|=q$ and let’s consider three cases.

Case 1: $q=3n$ for some integer $n.$ Then $x=x^q=(x^{n})^3$ for all $x \in F.$

Case 2: $q=3n+2$ for some integer $n.$ Then $x=x^{2-q}=(x^{-n})^3$ for all $0 \ne a \in F$ and clearly $0=0^3.$

So, in both cases 1 and 2, for every $x \in F,$ there exists $a \in F$ such that $x=a^3.$

Case 3: $q=3n+1$ for some integer $n.$ Since $F$ is finite, the multiplicative group $F^{\times}$ is cyclic. So $F^{\times}=\langle c \rangle.$ Let $x \in F$ and consider the sets

$A:=\{a^3: \ \ a \in F\}, \ \ B:=\{x-a^3: \ \ a \in F\}, \ \ \ C:=\{a^3-x: \ \ a \in F\}.$

Clearly $\{0\} \cup \{c^{3m}: \ \ 1 \le m \le n\} \subseteq A$ and $|A|=|B|=|C|.$ So $|A| \ge n+1$ and

$|A|+ |B|+ |C| =3|A| \ge 3n+3 > |F|.$

So at least two of the sets $A,B,C$ have non-empty intersection. If $A \cap B \neq \emptyset$ or $A \cap C \neq \emptyset,$ then $x=a^3+b^3$ for some $a,b \in F$ and we are done.
Now suppose that $B \cap C \ne \emptyset.$ So there exist $a,b \in F$ such that $x-a^3=b^3-x$ and so $2x=a^3+b^3.$ Since, as given in the problem, $\alpha^3=2$ for some $\alpha \ne 0,$ we have $2 \ne 0$ and $2^{-1}=\alpha^{-3}.$ Hence

$x=\alpha^{-3}(a^3+b^3)=(\alpha^{-1}a)^3+(\alpha^{-1}b)^3. \ \Box$

Remark 2. Regarding the third case in the solution of Problem 2, notice that, in fact, we have

$A= \{0\} \cup \{c^{3m}: \ \ 1 \le m \le n\}$

and so $|A|=n+1.$ The reason is that if $c^k=c^{3m}$ for some integers $k,m,$ then $c^{k-3m}=1$ and hence $k-3m$ must be divisible by $|F^{\times}|=3n$ implying that $k$ is divisible by $3.$

Maximum number of elements of the union of two proper subgroups of a finite group

Posted: December 2, 2018 in Elementary Algebra; Problems & Solutions, Groups and Fields
Tags: Klein four-group, union of subgroups

Problem 1. Let $G$ be a group and suppose that $H, K$ are two subgroups of $G.$ Show that if $G=H \cup K,$ then either $H=G$ or $K=G.$

Solution. If $H \subseteq K$ or $K \subseteq H,$ then $H \cup K=G$ gives $K=G$ or $H=G$ and we are done. Otherwise, there exist $h \in H \setminus K$ and $k \in K \setminus H.$ But then $hk \in G \setminus H \cup K,$ contradiction! $\Box$

Problem 2. Let $G$ be a finite group and suppose that $H, K$ are two subgroups of $G$ such that $H \ne G$ and $K \ne G.$ Show that $\displaystyle |H \cup K| \le \frac{3}{4}|G|.$

Solution. Recall that $\displaystyle |HK|=\frac{|H||K|}{|H \cap K|}$ and thus $\displaystyle \frac{|H||K|}{|H \cap K|} \le |G|.$ Hence $\displaystyle |H \cap K| \ge \frac{|H| |K|}{|G|}$ and so

$\displaystyle \begin{aligned}|H \cup K|=|H|+|K|-|H \cap K| \le |H|+|K|-\frac{|H| |K|}{|G|} =(a+b-ab)|G|, \ \ \ \ \ \ \ \ \ (*)\end{aligned}$

where $\displaystyle a:=\frac{|H|}{|G|}$ and $\displaystyle b:=\frac{|K|}{|G|}.$
Now, since $H \ne G$ and $K \ne G,$ we have $[G:H] \ge 2$ and $[G:K] \ge 2,$ i.e. $\displaystyle a \le \frac{1}{2}$ and $\displaystyle b \le \frac{1}{2}.$ So if we let $a':=1-2a$ and $b':=1-2b,$ then $a' \ge 0, \ b' \ge 0$ and thus

$\displaystyle a+b-ab=\frac{3}{4}-\frac{a'+b'+a'b'}{4} \le \frac{3}{4}.$

The result now follows from $(*). \ \Box$

Example 1. The upper bound $\displaystyle \frac{3}{4}|G|$ in Problem 2 cannot be improved, i.e. there exists a group $G$ and subgroups $H, K$ of $G$ such that $\displaystyle |H \cup K|=\frac{3}{4}|G|.$ An example is the Klein-four group $G=\mathbb{Z}_2 \times \mathbb{Z}_2$ and the subgroups $H:=\{(0,0), (1,0)\}$ and $K:=\{(0,0),(0,1)\}.$ Then $|G|=4$ and $\displaystyle |H \cup K|=3=\frac{3}{4}|G|.$

Example 2. We showed in Problem 1 that a group can never be equal to the union of two of its proper subgroups. But there are groups that are equal to the union of three of their proper subgroups. The smallest example, again, is the Klein-four group

$\mathbb{Z}_2 \times \mathbb{Z}_2= \{(0,0), (1,0)\} \cup \{(0,0), (0,1)\} \cup \{(0,0),(1,1)\}.$

Two elements of the same order of a group are conjugate, in somewhere!

Posted: November 24, 2018 in Elementary Algebra; Problems & Solutions, Groups and Fields
Tags: Cayley's theorem, conjugate, symmetric group

In this post, we give a nice little application of Cayley’s theorem.

Let $G$ be a group and let $g,h \in G.$ If $g,h$ are conjugate in $G,$ i.e. $g=xhx^{-1}$ for some $x \in G,$ then clearly $g^n=1$ if and only if $h^n=1.$ So $g,h$ have the same order. The converse however is false, i.e. if $g,h \in G$ have the same order, that does not imply $g,h$ are conjugate. For example, in an abelian group, two elements are conjugate if and only if they are equal but you can obviously have distinct elements of the same order in the group, e.g. in $\mathbb{Z}/3\mathbb{Z},$ both non-zero elements have the same order $3.$

We are now going to show that although two elements of the same order of a group might not be conjugate in the group, but they are certainly conjugate in some larger group.

Problem. Let $G$ be a group and suppose that $g,h \in G$ have the same order. Show that there exists a group $S \supseteq G$ such that $g,h$ are conjugate in $S.$

Solution. By Cayley’s theorem, we can embed $G$ into the symmetric group $S:=\text{Sym}(G)$ using the injective group homomorphism $f : G \to S$ defined by $f(x)=\sigma_x \in S,$ where $\sigma_x: G \to G$ is the permutation defined by $\sigma_x(y)=xy$ for all $y \in G.$ So we only need to show that $\sigma_g, \sigma_h$ are conjugate in $S.$ Well, let $|g|=|h|=n.$ Then the cycle decomposition of $\sigma_g, \sigma_h$ are in the form

$\sigma_g=(y_1, gy_1, \cdots , g^{n-1}y_1)(y_2, gy_2, \cdots , g^{n-1}y_2) \cdots$

and

$\sigma_h=(y_1, hy_1, \cdots , h^{n-1}y_1)(y_2, hy_2, \cdots , h^{n-1}y_2) \cdots$

So $\sigma_g, \sigma_h$ have the same cycle type and hence they are conjugate in $S. \ \Box$

Groups satisfying (xy)^n=x^ny^n

Posted: November 11, 2018 in Elementary Algebra; Problems & Solutions, Groups and Fields
Tags: exponent semigroup, Heisenberg group, n-abelian groups, torsion-free

Definition 1. Let $n$ be an integer. A group $G$ is called $n$ –abelian if $(xy)^n=x^ny^n$ for all $x,y \in G.$
In other words, $G$ is $n$ -abelian if the map $f : G \to G$ defined by $f(x)=x^n$ is a group homomorphism.

Definition 2. If $G$ is both $n$ -abelian and $m$ -abelian, for some integers $m,n,$ then $G$ is also $mn$ -abelian because then for $x,y \in G$ we will have

$(xy)^{mn}=((xy)^m)^n=(x^my^m)^n=x^{mn}y^{mn}.$

So the set

$\text{E}(G)=\{n \in \mathbb{Z}: \ \ (xy)^n=x^ny^n, \ \ \forall x,y \in G\},$

i.e., the set of those integers $n$ for which $G$ is $n$ -abelian, is a multiplicative subset of $\mathbb{Z}.$ Clearly $0,1 \in \text{E}(G).$ The set $\text{E}(G)$ is called the exponent semigroup of $G.$

Remark 1. Since $(xy)^n=x(yx)^{n-1}y,$ we have $(xy)^n=x^ny^n$ if and only if $(yx)^{n-1}=x^{n-1}y^{n-1}.$ So a group $G$ is $n$ -abelian if and only if $(yx)^{n-1}=x^{n-1}y^{n-1}$ or, equivalently, $(xy)^{1-n}=x^{1-n}y^{1-n}$ for all $x,y \in G.$ So a group $G$ is $n$ -abelian if and only if it is $(1-n)$ -abelian. In other words, $n \in \text{E}(G)$ if and only if $1-n \in \text{E}(G).$

Example 1. Every abelian group is obviously $n$ -abelian for all $n.$ It is also clear that $2$ -abelian groups are abelian because $xyxy=(xy)^2=x^2y^2=xxyy$ gives $yx=xy.$ As the next two examples show, there exists a non-abelian $n$ -abelian group for any $n > 2.$

Example 2. Let $n \ge 3$ be an odd integer and consider the Heisenberg group $G:=H(\mathbb{Z}/n\mathbb{Z}),$ which is a non-abelian group (why?). We show that $n, n+1 \in \text{E}(G),$ i.e. $G$ is both $n$ -abelian and $(n+1)$ -abelian. To see that, let

$g= \displaystyle \begin{pmatrix} 1 & a & b \\ 0 & 1 & c \\ 0 & 0 & 1 \end{pmatrix} \in G.$

An easy induction shows that

$\displaystyle g^m= \begin{pmatrix}1 & ma & mb + \frac{m(m-1)}{2}ac \\ 0 & 1 & mc \\ 0 & 0 & 1 \end{pmatrix}$

for all integers $m \ge 1.$ Thus $g^n=I,$ the identity matrix, and so $g^{n+1}=g,$ for all $g \in G.$
Hence $I=(xy)^n=x^ny^n$ and $xy=(xy)^{n+1}=x^{n+1}y^{n+1}$ for all $x,y \in G$ proving that $G$ is both $n$ -abelian and $(n+1)$ -abelian.

Remark 2. Notice that, in Example 2, if $n$ is even, then $\displaystyle \frac{n(n-1)}{2} \ne 0$ (as elements of $\mathbb{Z}/n\mathbb{Z})$ and so $g^n$ is not always the identity element in this case. However, there’s a way to fix this, as the next example shows. But first, notice that $H(\mathbb{Z}/n\mathbb{Z})$ can also be viewed as the group of triples

$G:=\{(a,b,c): \ \ a,b,c \in \mathbb{Z}/n\mathbb{Z}\}$

with multiplication defined by

$(a,b,c)(a',b',c')=(a+a',b+b'+ac',c+c').$

In the next example, we modify the above multiplication such that we get $g^n=1$ for all $g \in G.$

Example 3. Let $n \ge 3$ be any integer and consider the set $G:=\{(a,b,c): \ \ a,b,c \in \mathbb{Z}/n\mathbb{Z}\}.$ Define multiplication in $G$ by

$(a,b,c)*(a',b',c')=(a+a',b+b'+2ac',c+c').$

It’s easy to see that $(G,*)$ is a non-abelian group. We show that $n, n+1 \in \text{E}(G).$ Let $g=(a,b,c) \in G.$ A quick induction shows that

$g^m=(ma, mb+m(m-1)ac, mc)$

for all integers $m \ge 1.$ So $g^n=(0,0,0)=1_G$ for all $g \in G$ and thus $1_G=(xy)^n=x^ny^n$ for all $x,y \in G$ proving that $G$ is $n$ -abelian.
Also, since $g^{n+1}=g$ for all $g \in G,$ we have $xy=(xy)^{n+1}=x^{n+1}y^{n+1}$ and so $G$ is $(n+1)$ -abelian.

Problem 1. Let $G$ be a group. Show that

i) if $n, n+1 \in \text{E}(G)$ for some integer $n,$ then $x^n \in Z(G)$ for all $x \in G$

ii) if $n, n+1,n+2 \in \text{E}(G)$ for some integer $n,$ then $G$ is abelian.

Solution. i) Let $x,y \in G.$ We have

$xyx^ny^n=xy(xy)^n=(xy)^{n+1}=x^{n+1}y^{n+1}$

and so $yx^n=x^ny.$

ii) Let $x,y \in G.$ By i), we have $yx^n=x^ny$ and $yx^{n+1}=x^{n+1}y.$ Thus

$x^{n+1}y=yx^{n+1}=yx^nx=x^nyx$

and so $xy=yx. \ \Box$

Problem 2. Let $G$ be an $n$ -abelian group and let $x,y \in G.$ Show that

i) $x^{n-1}y^n=y^nx^{n-1}$

ii) $(xyx^{-1}y^{-1})^{n(n-1)}=1$

Solution. i) By Remark 1, $(ab)^{n-1}=b^{n-1}a^{n-1}$ for all $a,b \in G.$ Thus

$\begin{aligned} x^{n-1}y^{n-1}=(yx)^{n-1}=((yxy^{-1})y)^{n-1}=y^{n-1}(yxy^{-1})^{n-1}=y^{n-1}yx^{n-1}y^{-1}=y^nx^{n-1}y^{-1} \end{aligned}$

and the result follows.

ii) Again, using the Remark 1, we have

$\begin{aligned} (xyx^{-1}y^{-1})^{n(n-1)}=((x(yx^{-1}y^{-1}))^{n-1})^n=((yx^{-1}y^{-1})^{n-1}x^{n-1})^n=(yx^{-(n-1)}y^{-1}x^{n-1})^n \\ =y^n(x^{-(n-1)}y^{-1}x^{n-1})^n=y^nx^{-(n-1)}y^{-n}x^{n-1}=1, \ \ \ \text{by i)}. \ \Box \end{aligned}$

Remark 3. Let $G$ be an $n$ -abelian group for some integer $n \ge 2.$ An immediate result of Problem 2, ii), is that if either $G$ is torsion-free or $G$ is finite and $\text{gcd}(n(n-1), |G|)=1,$ then $G$ is abelian.

A simple property of subfields of R

Posted: September 23, 2018 in Elementary Algebra; Problems & Solutions, Groups and Fields

Problem. Show that if $\displaystyle F \subseteq \mathbb{R}$ is a field and $x_1, \cdots , x_n$ are positive real numbers such that $\sum_{i=1}^n x_i \in F$ and $x_i^2 \in F$ for all $i,$ then $x_i \in F$ for all $i.$

Solution. The proof is by induction over $n.$ There’s nothing to prove for $n=1.$ For $n\ge 2,$ since $\sum_{i=1}^n x_i \in F,$ we have

$\displaystyle \sum_{i=2}^n x_i \in F(x_1)=F + Fx_1$

and thus, by the induction hypothesis, $x_i \in F+ Fx_1$ for all $i \ge 2.$ So $x_2=a+bx_1$ for some $a,b \in F.$

If $b=0,$ then $x_2 \in F$ and so $\sum_{i \ne 2}x_i \in F.$ Hence, by the induction hypothesis, $x_i \in F$ for all $i.$

If $a=0,$ then $x_2=bx_1$ (so $b > 0$ because $x_1,x_2 > 0$ ). Thus

$\displaystyle \sum_{i=1}^n x_i = (b+1)x_1 + \sum_{i \ge 3} x_i \in F$

and so, by the induction hypothesis, $x_i \in F$ for all $i.$

If $a, b \ne 0,$ then $x_2^2=a^2+b^2x_1^2+2abx_1$ gives $x_1 \in F$ and so $\sum_{i \ge 2} x_i \in F$ implying, again by the induction hypothesis,that $x_i \in F$ for all $i. \ \Box$

Example. Show that $\mathbb{Q}(\sqrt{2}+ \sqrt{5}+ \cdots +\sqrt{n^2+1})=\mathbb{Q}(\sqrt{2}, \sqrt{5}, \cdots , \sqrt{n^2+1}).$ for all integers $n \ge 1.$

Solution. Let $F:=\mathbb{Q}(x_1 + \cdots + x_n),$ where $x_i=\sqrt{i^2+1}$ for all $i.$ Since $\sum_{i=1}^n x_i \in F$ and $x_i^2 \in F$ for all $i,$ we have, by the above problem, $x_i \in F$ for all $i.$ Thus $\mathbb{Q}(x_1, \cdots , x_n) \subseteq F$ and we are done because obviously $F \subseteq \mathbb{Q}(x_1, \cdots , x_n).$

Maximum order of abelian subgroups in a symmetric group

Posted: April 21, 2012 in Elementary Algebra; Problems & Solutions, Groups and Fields
Tags: abelian subgroups, maximum order, symmetric group

For any set $X,$ we denote by ${\rm{Sym}}(X)$ the group of bijective maps from $X$ to $X.$

Problem. Let $\alpha : \mathbb{N} \longrightarrow [1, \infty)$ be any map which satisfies the following two conditions: $\alpha(p) \geq p$ and $\alpha(p+q) \geq \alpha(p) \alpha(q)$ for all $p,q \in \mathbb{N}.$ Let $X$ be a set with $|X|=n.$ Prove that if $G$ is an abelian subgroup of ${\rm{Sym}}(X),$ then $|G| \leq \alpha(n).$

Solution. The proof is by induction on $n.$ If $n=1,$ then $|G|=1 \leq \alpha(1).$ Let $X$ be a set with $|X|= n \geq 2$ and suppose that the claim is true for any set of size $< n.$ Let $G$ be an abelian subgroup of ${\rm{Sym}}(X).$ Clearly $gx=g(x), \ g \in G, x \in X,$ defines an action of $G$ on $X.$ Let $X_1, \ldots , X_k$ be the orbits corresponding to this action and consider two cases.

Case 1. $k=1$ : Fix an element $x_1 \in X.$ Then $X=X_1=Gx_1.$ Suppose that $g_1x_1=x_1$ for some $g_1 \in G$ and let $x \in X.$ Then $x=gx_1$ for some $g \in G.$ Thus, since $G$ is abelian, we have

$x=gx_1=gg_1x_1=g_1gx_1=g_1x.$

Hence $g_1x=x$ for all $x \in X$ and thus $g_1=1.$ So the stabilizer of $x_1$ is trivial and therefore, by the orbit-stabilizer theorem, $|G|=|X|=n \leq \alpha(n).$

Case 2. $k \geq 2$ : Let $|X_i|=n_i, \ i=1,2, \ldots, k.$ Clearly $\sum_{i=1}^k n_i=n$ and, since $k \geq 2,$ we have $n_i < n$ for all $i.$ For every $g \in G$ and $1 \leq i \leq k$ let $g_i=g|_{X_i},$ the restriction of $g$ to $X_i,$ and put

$G_i=\{g_i: \ g \in G\}.$

Then $g_i \in {\rm{Sym}}(X_i)$ and $G_i$ is an abelian subgroup of ${\rm{Sym}}(X_i).$ Thus, by the induction hypothesis

$|G_i| \leq \alpha(n_i),$

for all $i.$ Now, define $\varphi : G \longrightarrow \bigoplus_{i=1}^k G_i$ by $\varphi(g)=(g_1, g_2, \ldots , g_k)$ for all $g \in G.$ It is obvious that $\varphi$ is one-to-one and so

$|G| \leq |\bigoplus_{i=1}^k G_i|=\prod_{i=1}^k |G_i| \leq \prod_{i=1}^k \alpha(n_i) \leq \alpha(\sum_{i=1}^k n_i)=\alpha(n). \ \Box$

Remark. The map $\alpha: \mathbb{N} \longrightarrow [1, \infty)$ defined by $\alpha(p)=3^{p/3},$ for all $p \in \mathbb{N},$ satisfies both conditions in the above Problem. So if $|X|=n$ and if $G$ is an abelian subgroup of ${\rm{Sym}}(X),$ then $|G| \leq 3^{n/3}.$

Degree of an irreducible factor of composition of two polynomials

Posted: November 17, 2011 in Elementary Algebra; Problems & Solutions, Groups and Fields
Tags: composite of two polynomials, degree of irreducible factors

Problem. Let $F$ be a field and suppose that $f(x),g(x), p(x)$ are three polynomials in $F[x].$ Prove that if both $f(x)$ and $p(x)$ are irreducible and $p(x) \mid f(g(x)),$ then $\deg f(x) \mid \deg p(x).$

Solution. Let $\mathfrak{m}$ and $\mathfrak{n}$ be the ideals of $F[x]$ generated by $f(x)$ and $p(x),$ respectively. Let $E=F[x]/\mathfrak{m}$ and $L = F[x]/\mathfrak{n}.$ Since both $f(x)$ and $p(x)$ are irreducible, $E$ and $L$ are field extensions of $F.$ Now, define the map $\varphi : E \longrightarrow L$ by $\varphi(h(x) + \mathfrak{m})=h(g(x)) + \mathfrak{n},$ for all $h(x) \in F[x].$ We first show that $\varphi$ is well-defined. To see this, suppose that $h(x) \in \mathfrak{m}.$ Then $h(x)=f(x)u(x)$ for some $u(x) \in F[x]$ and hence $h(g(x)) = f(g(x))u(g(x)) \in \mathfrak{n},$ because $p(x) \mid f(g(x)).$ So $\varphi$ is well-defined. Now $\varphi$ is clearly a ring homomorphism and, since $E$ is a field and $\ker \varphi$ is an ideal of $E,$ we must have $\ker \varphi = \{0\}.$
Therefore we may assume that $F \subseteq E \subseteq L$ and hence