Example17.11

The polynomial $x^2 - 2 \in {\mathbb Q}[x]$ is irreducible since it cannot be factored any further over the rational numbers. Similarly, $x^2 + 1$ is irreducible over the real numbers.

Example17.12

The polynomial $p(x) = x^3 + x^2 + 2$ is irreducible over ${\mathbb Z}_3[x]\text{.}$ Suppose that this polynomial was reducible over ${\mathbb Z}_3[x]\text{.}$ By the division algorithm there would have to be a factor of the form $x - a\text{,}$ where $a$ is some element in ${\mathbb Z}_3[x]\text{.}$ Hence, it would have to be true that $p(a) = 0\text{.}$ However,

Therefore, $p(x)$ has no zeros in ${\mathbb Z}_3$ and must be irreducible.

Lemma17.13

Let $p(x) \in {\mathbb Q}[x]\text{.}$ Then

where $r, s, a_0, \ldots, a_n$ are integers, the $a_i$'s are relatively prime, and $r$ and $s$ are relatively prime.

Proof

Suppose that

where the $b_i$'s and the $c_i$'s are integers. We can rewrite $p(x)$ as

where $d_0, \ldots, d_n$ are integers. Let $d$ be the greatest common divisor of $d_0, \ldots, d_n\text{.}$ Then

where $d_i = d a_i$ and the $a_i$'s are relatively prime. Reducing $d /(c_0 \cdots c_n)$ to its lowest terms, we can write

where $\gcd(r,s) = 1\text{.}$

Theorem17.14Gauss's Lemma

Let $p(x) \in {\mathbb Z}[x]$ be a monic polynomial such that $p(x)$ factors into a product of two polynomials $\alpha(x)$ and $\beta(x)$ in ${\mathbb Q}[x]\text{,}$ where the degrees of both $\alpha(x)$ and $\beta(x)$ are less than the degree of $p(x)\text{.}$ Then $p(x) = a(x) b(x)\text{,}$ where $a(x)$ and $b(x)$ are monic polynomials in ${\mathbb Z}[x]$ with $\deg \alpha(x) = \deg a(x)$ and $\deg \beta(x) = \deg b(x)\text{.}$

Proof

By Lemma 17.13, we can assume that

where the $a_i$'s are relatively prime and the $b_i$'s are relatively prime. Consequently,

where $c/d$ is the product of $c_1/d_1$ and $c_2/d_2$ expressed in lowest terms. Hence, $d p(x) = c \alpha_1(x) \beta_1(x)\text{.}$

If $d = 1\text{,}$ then $c a_m b_n = 1$ since $p(x)$ is a monic polynomial. Hence, either $c=1$ or $c = -1\text{.}$ If $c=1\text{,}$ then either $a_m = b_n = 1$ or $a_m = b_n = -1\text{.}$ In the first case $p(x) = \alpha_1(x) \beta_1(x)\text{,}$ where $\alpha_1(x)$ and $\beta_1(x)$ are monic polynomials with $\deg \alpha(x) = \deg \alpha_1(x)$ and $\deg \beta(x) = \deg \beta_1(x)\text{.}$ In the second case $a(x) = -\alpha_1(x)$ and $b(x) = -\beta_1(x)$ are the correct monic polynomials since $p(x) = (-\alpha_1(x))(- \beta_1(x)) = a(x) b(x)\text{.}$ The case in which $c = -1$ can be handled similarly.

Now suppose that $d \neq 1\text{.}$ Since $\gcd(c, d) = 1\text{,}$ there exists a prime $p$ such that $p \mid d$ and $p \notdivide c\text{.}$ Also, since the coefficients of $\alpha_1(x)$ are relatively prime, there exists a coefficient $a_i$ such that $p \notdivide a_i\text{.}$ Similarly, there exists a coefficient $b_j$ of $\beta_1(x)$ such that $p \notdivide b_j\text{.}$ Let $\alpha_1'(x)$ and $\beta_1'(x)$ be the polynomials in ${\mathbb Z}_p[x]$ obtained by reducing the coefficients of $\alpha_1(x)$ and $\beta_1(x)$ modulo $p\text{.}$ Since $p \mid d\text{,}$ $\alpha_1'(x) \beta_1'(x) = 0$ in ${\mathbb Z}_p[x]\text{.}$ However, this is impossible since neither $\alpha_1'(x)$ nor $\beta_1'(x)$ is the zero polynomial and ${\mathbb Z}_p[x]$ is an integral domain. Therefore, $d=1$ and the theorem is proven.

Corollary17.15

Let $p(x) = x^n + a_{n - 1} x^{n - 1} + \cdots + a_0$ be a polynomial with coefficients in ${\mathbb Z}$ and $a_0 \neq 0\text{.}$ If $p(x)$ has a zero in ${\mathbb Q}\text{,}$ then $p(x)$ also has a zero $\alpha$ in ${\mathbb Z}\text{.}$ Furthermore, $\alpha$ divides $a_0\text{.}$

Proof

Let $p(x)$ have a zero $a \in {\mathbb Q}\text{.}$ Then $p(x)$ must have a linear factor $x-a\text{.}$ By Gauss's Lemma, $p(x)$ has a factorization with a linear factor in ${\mathbb Z}[x]\text{.}$ Hence, for some $\alpha \in {\mathbb Z}$

Thus $a_0 /\alpha \in {\mathbb Z}$ and so $\alpha \mid a_0\text{.}$

Example17.16

Let $p(x) = x^4 - 2 x^3 + x + 1\text{.}$ We shall show that $p(x)$ is irreducible over ${\mathbb Q}[x]\text{.}$ Assume that $p(x)$ is reducible. Then either $p(x)$ has a linear factor, say $p(x) = (x - \alpha) q(x)\text{,}$ where $q(x)$ is a polynomial of degree three, or $p(x)$ has two quadratic factors.

If $p(x)$ has a linear factor in ${\mathbb Q}[x]\text{,}$ then it has a zero in ${\mathbb Z}\text{.}$ By Corollary 17.15, any zero must divide 1 and therefore must be $\pm 1\text{;}$ however, $p(1) = 1$ and $p(-1)= 3\text{.}$ Consequently, we have eliminated the possibility that $p(x)$ has any linear factors.

Therefore, if $p(x)$ is reducible it must factor into two quadratic polynomials, say

where each factor is in ${\mathbb Z}[x]$ by Gauss's Lemma. Hence,

Since $bd = 1\text{,}$ either $b = d = 1$ or $b = d = -1\text{.}$ In either case $b = d$ and so

Since $a + c = -2\text{,}$ we know that $-2b = 1\text{.}$ This is impossible since $b$ is an integer. Therefore, $p(x)$ must be irreducible over ${\mathbb Q}\text{.}$

Theorem17.17Eisenstein's Criterion

Let $p$ be a prime and suppose that

If $p \mid a_i$ for $i = 0, 1, \ldots, n-1\text{,}$ but $p \notdivide a_n$ and $p^2 \notdivide a_0\text{,}$ then $f(x)$ is irreducible over ${\mathbb Q}\text{.}$

Proof

By Gauss's Lemma, we need only show that $f(x)$ does not factor into polynomials of lower degree in ${\mathbb Z}[x]\text{.}$ Let

be a factorization in ${\mathbb Z}[x]\text{,}$ with $b_r$ and $c_s$ not equal to zero and $r, s \lt n\text{.}$ Since $p^2$ does not divide $a_0 = b_0 c_0\text{,}$ either $b_0$ or $c_0$ is not divisible by $p\text{.}$ Suppose that $p \notdivide b_0$ and $p \mid c_0\text{.}$ Since $p \notdivide a_n$ and $a_n = b_r c_s\text{,}$ neither $b_r$ nor $c_s$ is divisible by $p\text{.}$ Let $m$ be the smallest value of $k$ such that $p \notdivide c_k\text{.}$ Then

is not divisible by $p\text{,}$ since each term on the right-hand side of the equation is divisible by $p$ except for $b_0 c_m\text{.}$ Therefore, $m = n$ since $a_i$ is divisible by $p$ for $m \lt n\text{.}$ Hence, $f(x)$ cannot be factored into polynomials of lower degree and therefore must be irreducible.

Example17.18

The polynomial

is easily seen to be irreducible over ${\mathbb Q}$ by Eisenstein's Criterion if we let $p = 3\text{.}$

Example17.19

The polynomial $x^2$ in $F[x]$ generates the ideal $\langle x^2 \rangle$ consisting of all polynomials with no constant term or term of degree 1.

Theorem17.20

If $F$ is a field, then every ideal in $F[x]$ is a principal ideal.

Proof

Let $I$ be an ideal of $F[x]\text{.}$ If $I$ is the zero ideal, the theorem is easily true. Suppose that $I$ is a nontrivial ideal in $F[x]\text{,}$ and let $p(x) \in I$ be a nonzero element of minimal degree. If $\deg p(x)= 0\text{,}$ then $p(x)$ is a nonzero constant and 1 must be in $I\text{.}$ Since 1 generates all of $F[x]\text{,}$ $\langle 1 \rangle = I = F[x]$ and $I$ is again a principal ideal.

Now assume that $\deg p(x) \geq 1$ and let $f(x)$ be any element in $I\text{.}$ By the division algorithm there exist $q(x)$ and $r(x)$ in $F[x]$ such that $f(x) = p(x) q(x) + r(x)$ and $\deg r(x) \lt \deg p(x)\text{.}$ Since $f(x), p(x) \in I$ and $I$ is an ideal, $r(x) = f(x) - p(x) q(x)$ is also in $I\text{.}$ However, since we chose $p(x)$ to be of minimal degree, $r(x)$ must be the zero polynomial. Since we can write any element $f(x)$ in $I$ as $p(x) q(x)$ for some $q(x) \in F[x]\text{,}$ it must be the case that $I = \langle p(x) \rangle\text{.}$

Example17.21

It is not the case that every ideal in the ring $F[x,y]$ is a principal ideal. Consider the ideal of $F[x, y]$ generated by the polynomials $x$ and $y\text{.}$ This is the ideal of $F[x, y]$ consisting of all polynomials with no constant term. Since both $x$ and $y$ are in the ideal, no single polynomial can generate the entire ideal.

Theorem17.22

Let $F$ be a field and suppose that $p(x) \in F[x]\text{.}$ Then the ideal generated by $p(x)$ is maximal if and only if $p(x)$ is irreducible.

Proof

Suppose that $p(x)$ generates a maximal ideal of $F[x]\text{.}$ Then $\langle p(x) \rangle$ is also a prime ideal of $F[x]\text{.}$ Since a maximal ideal must be properly contained inside $F[x]\text{,}$ $p(x)$ cannot be a constant polynomial. Let us assume that $p(x)$ factors into two polynomials of lesser degree, say $p(x) = f(x) g(x)\text{.}$ Since $\langle p(x) \rangle$ is a prime ideal one of these factors, say $f(x)\text{,}$ is in $\langle p(x) \rangle$ and therefore be a multiple of $p(x)\text{.}$ But this would imply that $\langle p(x) \rangle \subset \langle f(x) \rangle\text{,}$ which is impossible since $\langle p(x) \rangle$ is maximal.

Conversely, suppose that $p(x)$ is irreducible over $F[x]\text{.}$ Let $I$ be an ideal in $F[x]$ containing $\langle p(x) \rangle\text{.}$ By Theorem 17.20, $I$ is a principal ideal; hence, $I = \langle f(x) \rangle$ for some $f(x) \in F[x]\text{.}$ Since $p(x) \in I\text{,}$ it must be the case that $p(x) = f(x) g(x)$ for some $g(x) \in F[x]\text{.}$ However, $p(x)$ is irreducible; hence, either $f(x)$ or $g(x)$ is a constant polynomial. If $f(x)$ is constant, then $I = F[x]$ and we are done. If $g(x)$ is constant, then $f(x)$ is a constant multiple of $I$ and $I = \langle p(x) \rangle\text{.}$ Thus, there are no proper ideals of $F[x]$ that properly contain $\langle p(x)\rangle\text{.}$