Difference between revisions of "Abstract Algebra: Groups"

Recall that an operation ${\displaystyle \cdot }$ on ${\displaystyle S}$ is said to be associative if for all ${\displaystyle a,b,c\in S}$ we have that ${\displaystyle a\cdot (b\cdot c)=(a\cdot b)\cdot c}$ and ${\displaystyle \cdot }$ is said to be commutative if for all ${\displaystyle a,b\in S}$ we have that ${\displaystyle a\cdot b=b\cdot a}$.

An element ${\displaystyle e\in S}$ is the identity element of ${\displaystyle S}$ under ${\displaystyle \cdot }$ if for all ${\displaystyle a\in S}$ we have that ${\displaystyle a\cdot e=a}$ and ${\displaystyle e\cdot a=a}$.

We can now begin to describe our first type of algebraic structures known as groups, which are a set ${\displaystyle G}$ equipped with a binary operation ${\displaystyle \cdot }$ that is associative, contains an identity element, and contains inverse elements under ${\displaystyle \cdot }$ for each element in ${\displaystyle G}$.

Definition: A Group is a pair ${\displaystyle (G,\cdot )}$ where ${\displaystyle G}$ is a set and ${\displaystyle \cdot }$ is a binary operation on ${\displaystyle G}$ with the following properties:

1. For all ${\displaystyle a,b,c\in G}$, ${\displaystyle a\cdot (b\cdot c)=(a\cdot b)\cdot c}$ (Associativity of ${\displaystyle \cdot }$).
2. There exists an ${\displaystyle e\in G}$ such that for all ${\displaystyle a\in G}$, ${\displaystyle a\cdot e=a}$ and ${\displaystyle e\cdot a=a}$ (The existence of an Identity Element).
3. For all ${\displaystyle a\in G}$ there exists an ${\displaystyle a^{-1}\in G}$ such that ${\displaystyle a\cdot a^{-1}=e}$ and ${\displaystyle a^{-1}\cdot a=e}$ (The existence of inverses).

Furthermore, if ${\displaystyle G}$ is a finite set then the group ${\displaystyle (G,\cdot )}$ is said to be a Finite Group and if ${\displaystyle G}$ is an infinite set then the group ${\displaystyle (G,\cdot )}$ is said to be an Infinite Group. More generally, the Order of ${\displaystyle (G,\cdot )}$ (or **Size of ${\displaystyle (G,\cdot )}$) is the size of ${\displaystyle G}$ and is denoted ${\displaystyle |G|}$.

When we use the multiplication symbol ${\displaystyle \cdot }$ to denote the operation on ${\displaystyle G}$, we often call ${\displaystyle G}$ a “multiplicative group”. When the operation of the group is instead denoted by ${\displaystyle +}$ (instead of ${\displaystyle \cdot }$) then we often call ${\displaystyle G}$ an “additive group”, and we write the inverse of each ${\displaystyle a\in G}$ as ${\displaystyle -a}$ (instead of ${\displaystyle a^{-1}}$).

Some of the sets and binary operations we have already seen can be considered groups. For example, ${\displaystyle (\mathbb {R} ,+)}$ is a group under standard addition ${\displaystyle +}$ since the sum of any two real numbers is a real number, ${\displaystyle +}$, is associative, an additive identity ${\displaystyle 0\in \mathbb {R} }$ exists and inverse elements exist for every ${\displaystyle a\in \mathbb {R} }$ (namely ${\displaystyle -a\in \mathbb {R} }$).

Furthermore, ${\displaystyle (\mathbb {Z} ,+)}$ is also a group under the operation of standard addition since the sum of any two integers is an integer, addition is associative, the additivity identity is ${\displaystyle 0\in \mathbb {Z} }$, and for all ${\displaystyle a\in \mathbb {Z} }$ we have ${\displaystyle -a\in \mathbb {Z} }$ as additive inverses.

We will examine many other (more interesting) groups later on, but for now, let's look at an example of a set and a binary operation that does NOT form a group.

Example 1

Consider the set of integers ${\displaystyle \mathbb {Z} }$ and define ${\displaystyle *}$ for all ${\displaystyle a,b\in \mathbb {Z} }$ by:

${\displaystyle {\begin{aligned}\quad a*b=a+2b\end{aligned}}}$

(Where the ${\displaystyle +}$ on the righthand side is usual addition of numbers). We will show that ${\displaystyle (\mathbb {Z} ,*)}$ is NOT a group by showing that ${\displaystyle *}$ is not associative. Let ${\displaystyle a,b,c\in \mathbb {Z} }$. Then ${\displaystyle *}$ is not associative since:

${\displaystyle {\begin{aligned}\quad a*(b*c)=a*(b+2c)=a+2(b+2c)=a+2b+4c\end{aligned}}}$

${\displaystyle {\begin{aligned}\quad (a*b)*c=(a+2b)*c=(a+2b)+2c=a+2b+2c\end{aligned}}}$

Clearly ${\displaystyle a*(b*c)\neq (a*b)*c}$ so ${\displaystyle \mathbb {Z} }$ does not form a group under the operation ${\displaystyle *}$.

Basic Theorems Regarding Groups

Recall that a group ${\displaystyle (G,\cdot )}$ is a set ${\displaystyle G}$ with a binary operation ${\displaystyle \cdot }$ such that:

• 1) ${\displaystyle \cdot }$ is associative, i.e., for all ${\displaystyle a,b,c\in G}$, ${\displaystyle a\cdot (b\cdot c)=(a\cdot b)\cdot c)}$.

• 2) There exists an identity element ${\displaystyle e\in G}$ such that ${\displaystyle a\cdot e=a=e\cdot a}$ for all ${\displaystyle a\in G}$.

• 3) For each ${\displaystyle a\in G}$ there exists an ${\displaystyle a^{-1}\in G}$ such that ${\displaystyle a\cdot a^{-1}=a^{-1}\cdot a=e}$.

We will now look at some rather basic results regarding groups which we can derive from the group axioms above.

Proposition 1: Let ${\displaystyle (G,\cdot )}$ be a group and let ${\displaystyle e}$ be the identity for this group. Then:

a) The identity element ${\displaystyle e\in G}$ is unique.
b) For each ${\displaystyle a\in G}$, the corresponding inverse ${\displaystyle a^{-1}\in G}$ is unique.
c) For each ${\displaystyle a\in G}$, ${\displaystyle (a^{-1})^{-1}=a}$.
d) For all ${\displaystyle a,b\in G}$, ${\displaystyle (a\cdot b)^{-1}=b^{-1}\cdot a^{-1}}$.
e) For all ${\displaystyle a,b\in G}$, if ${\displaystyle a\cdot b=e}$ then ${\displaystyle a=b^{-1}}$ and ${\displaystyle b=a^{-1}}$.

f) If ${\displaystyle a^{2}=a}$ then ${\displaystyle a=e}$.

• Proof of a) Suppose that ${\displaystyle e}$ and ${\displaystyle e'}$ are both identities for ${\displaystyle \cdot }$. Then:

${\displaystyle {\begin{aligned}\quad e=e\cdot e=e\cdot e'=e'\cdot e'=e'\end{aligned}}}$

• Therefore ${\displaystyle e=e'}$ so the identity for ${\displaystyle \cdot }$ is unique. ${\displaystyle \blacksquare }$

• Proof of b) Suppose that ${\displaystyle a^{-1}\in G}$ and ${\displaystyle a^{-1'}\in G}$ are both inverses for ${\displaystyle a\in G}$ under ${\displaystyle \cdot }$. Then:

${\displaystyle {\begin{aligned}\quad a^{-1}=a^{-1}\cdot e=a^{-1}\cdot (a\cdot a^{-1'})=(a^{-1}\cdot a)*a^{-1}=e\cdot a^{-1'}=a^{-1'}\end{aligned}}}$

• Therefore ${\displaystyle a^{-1}=a^{-1'}}$ so the inverse for ${\displaystyle a}$ is unique. ${\displaystyle \blacksquare }$

• Proof of c) Let ${\displaystyle a\in G}$. Then ${\displaystyle (a^{-1})^{-1}}$ is the inverse to ${\displaystyle a^{-1}}$. However, the inverse to ${\displaystyle a^{-1}}$ is ${\displaystyle a}$ and by (b) we have shown that the inverse of each element in ${\displaystyle G}$ is unique. Therefore ${\displaystyle a=(a^{-1})^{-1}}$. ${\displaystyle \blacksquare }$

• Proof of d) If we apply the operation ${\displaystyle \cdot }$ between ${\displaystyle b^{-1}\cdot a^{-1}}$ and ${\displaystyle (a\cdot b)}$ we get:

${\displaystyle {\begin{aligned}\quad (a\cdot b)\cdot [b^{-1}\cdot a^{-1}]&=a\cdot [(b\cdot b^{-1})\cdot a^{-1}]\\\quad &=a\cdot [e\cdot a^{-1}]\\\quad &=a\cdot a^{-1}\\\quad &=e\end{aligned}}}$

• Therefore the inverse of ${\displaystyle (a\cdot b)}$ is ${\displaystyle b^{-1}\cdot a^{-1}}$. We also have that the invere of ${\displaystyle (a\cdot b)}$ is ${\displaystyle (a\cdot b)^{-1}}$. By (b), the inverse of ${\displaystyle (a\cdot b)}$ is unique and so:

${\displaystyle {\begin{aligned}\quad (a\cdot b)^{-1}=b^{-1}\cdot a^{-1}\quad \blacksquare \end{aligned}}}$

• Proof of e) Suppose that ${\displaystyle a\cdot b=e}$. Then:

${\displaystyle {\begin{aligned}\quad a\cdot b&=e\\\quad (a\cdot b)\cdot b^{-1}&=e\cdot b^{-1}\\\quad a\cdot (b\cdot b^{-1})&=b^{-1}\\\quad a\cdot e&=b^{-1}\\\quad a&=b^{-1}\end{aligned}}}$

• Similarly:

${\displaystyle {\begin{aligned}\quad a\cdot b&=e\\\quad a^{-1}\cdot (a\cdot b)&=a^{-1}\cdot e\\\quad (a^{-1}\cdot a)\cdot b&=a^{-1}\\\quad e\cdot b&=a^{-1}\\\quad b&=a^{-1}\quad \blacksquare \end{aligned}}}$

• Proof of f) Suppose that ${\displaystyle a^{2}=a\cdot a=a}$. Then:

${\displaystyle {\begin{aligned}\quad a^{2}&=a\\\quad a\cdot a&=a\\\quad a^{-1}\cdot (a\cdot a)&=a^{-1}\cdot a\\\quad (a^{-1}\cdot a)\cdot a&=e\\\quad e\cdot a&=e\\\quad a&=e\end{aligned}}}$

• Hence ${\displaystyle a=e}$. Alternatively we see that if ${\displaystyle a\cdot a=a}$ then the inverse of ${\displaystyle a}$ with respect to ${\displaystyle \cdot }$ is ${\displaystyle e}$, that is ${\displaystyle a^{-1}=e}$. Multiplying both sides of this equation by ${\displaystyle a}$ gives us that ${\displaystyle a=e}$. ${\displaystyle \blacksquare }$

Cancellation Law

We will now look at another important property of groups called the cancellation law.

Theorem 1 (The Cancellation Law for Groups): Let ${\displaystyle (G,\cdot )}$ be a group and let ${\displaystyle a,b,c\in G}$. If ${\displaystyle a\cdot b=a\cdot c}$ or ${\displaystyle b\cdot a=c\cdot a}$ then ${\displaystyle b=c}$.

• Proof: Let ${\displaystyle a^{-1}\in G}$ denote the inverse of ${\displaystyle a}$ under ${\displaystyle \cdot }$. Suppose that ${\displaystyle a\cdot b=a\cdot c}$. Then:

${\displaystyle {\begin{aligned}\quad a\cdot b&=a\cdot c\\\quad (a^{-1}\cdot a)\cdot b&=(a^{-1}\cdot a)\cdot c\\\quad e\cdot b&=e\cdot c\\\quad b&=c\end{aligned}}}$

• Similarly, suppose now that ${\displaystyle b\cdot a=c\cdot a}$. Then:

${\displaystyle {\begin{aligned}\quad b\cdot a&=c\cdot a\\\quad (b\cdot a)\cdot a^{-1}&=(c\cdot a)\cdot a^{-1}\\\quad b\cdot (a\cdot a^{-1})&=c\cdot (a\cdot a^{-1})\\\quad b\cdot e&=c\cdot e\\\quad b&=c\quad \blacksquare \end{aligned}}}$

It is very important to note that the cancellation law holds with regards to the operation ${\displaystyle \cdot }$ for any group ${\displaystyle (G,\cdot )}$. We will see that the cancellation law does not necessarily hold with respect to an operation on a set when we look at algebraic structures with two defined operations.

It is also important to note that if ${\displaystyle a\cdot b=c\cdot a}$ or ${\displaystyle b\cdot a=a\cdot c}$ then we cannot necessarily deduce that ${\displaystyle b=c}$ because we would then require the additional property that ${\displaystyle \cdot }$ is commutative which is not one of the group axioms (but instead one of the Abelian group axioms).

Licensing

Content obtained and/or adapted from:

• Abstract Algebra, mathonline.wikidot.com under a CC BY-SA license