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Polynomial Rings
If R is a ring, then  , the ring of polynomials in x with coefficients in R, consists of all formal sums 
 , where  for all but finitely many values of i.
If  is a nonzero polynomial, the degree is the largest  such that  . The zero
polynomial has degree  .
 becomes a ring with the usual operations of polynomial addition and multiplication.
If F is a field, the units in  are exactly the nonzero elements of F.
If  is a field,  , and  , there are unique polynomials  such
that
Let R be an integral domain. An element  is irreducible if  , x is not a unit, and if 
implies either y is a unit or z is a unit.
Let R be an integral domain. An element  is prime if  , x is not a unit, and  implies 
 or  .
In an integral domain, primes are irreducible.
Let F be a field. If  are not both zero, then  and  have a greatest common
divisor which is unique up to multiplication by units (elements of F).
Let F be a field, let  , and let  be a greatest common divisor of  and  .
There are polynomials  such that
If R is a ring, the ring of polynomials in x with coefficients in R is denoted  . It consists of all formal
sums
Here  for all but finitely many values of i.
If the idea of "formal sums" worries you, replace a formal sum with the infinite vector whose components are
the coefficients of the sum:
Page 2


Polynomial Rings
If R is a ring, then  , the ring of polynomials in x with coefficients in R, consists of all formal sums 
 , where  for all but finitely many values of i.
If  is a nonzero polynomial, the degree is the largest  such that  . The zero
polynomial has degree  .
 becomes a ring with the usual operations of polynomial addition and multiplication.
If F is a field, the units in  are exactly the nonzero elements of F.
If  is a field,  , and  , there are unique polynomials  such
that
Let R be an integral domain. An element  is irreducible if  , x is not a unit, and if 
implies either y is a unit or z is a unit.
Let R be an integral domain. An element  is prime if  , x is not a unit, and  implies 
 or  .
In an integral domain, primes are irreducible.
Let F be a field. If  are not both zero, then  and  have a greatest common
divisor which is unique up to multiplication by units (elements of F).
Let F be a field, let  , and let  be a greatest common divisor of  and  .
There are polynomials  such that
If R is a ring, the ring of polynomials in x with coefficients in R is denoted  . It consists of all formal
sums
Here  for all but finitely many values of i.
If the idea of "formal sums" worries you, replace a formal sum with the infinite vector whose components are
the coefficients of the sum:
All of the operations which I'll define using formal sums can be defined using vectors. But it's traditional to
represent polynomials as formal sums, so this is what I'll do.
A nonzero polynomial  has degree n if  and  , and n is the largest integer with this
property. The zero polynomial is defined by convention to have degree  . (This is necessary in order to
make the dgree formulas work out.) Alternatively, you can say that the degree of the zero polynomial is
undefined; in that case, you will need to make minor changes to some of the results below.
Polynomials are added componentwise, and multiplied using the "convolution" formula:
These formulas say that you compute sums and products as usual.
Example. ( Polynomial arithmetic) In  ,
Let R be an integral domain. Then If  , write  to denote the degree of f. It's easy to show that the
degree function satisfies the following properties:
The verifications amount to writing out the formal sums, with a little attention paid to the case of the zero
polynomial. These formulas {\it do} work if either f or g is equal to the zero polynomial, provided that  is
understood to behave in the obvious ways (e.g.  for any  ).
Example. ( Degrees of polynomials) Note that in  ,
This shows that equality might not hold in  .
The equality  might not hold if R is not an integral domain. For example, take 
 . Then (since  ),
Page 3


Polynomial Rings
If R is a ring, then  , the ring of polynomials in x with coefficients in R, consists of all formal sums 
 , where  for all but finitely many values of i.
If  is a nonzero polynomial, the degree is the largest  such that  . The zero
polynomial has degree  .
 becomes a ring with the usual operations of polynomial addition and multiplication.
If F is a field, the units in  are exactly the nonzero elements of F.
If  is a field,  , and  , there are unique polynomials  such
that
Let R be an integral domain. An element  is irreducible if  , x is not a unit, and if 
implies either y is a unit or z is a unit.
Let R be an integral domain. An element  is prime if  , x is not a unit, and  implies 
 or  .
In an integral domain, primes are irreducible.
Let F be a field. If  are not both zero, then  and  have a greatest common
divisor which is unique up to multiplication by units (elements of F).
Let F be a field, let  , and let  be a greatest common divisor of  and  .
There are polynomials  such that
If R is a ring, the ring of polynomials in x with coefficients in R is denoted  . It consists of all formal
sums
Here  for all but finitely many values of i.
If the idea of "formal sums" worries you, replace a formal sum with the infinite vector whose components are
the coefficients of the sum:
All of the operations which I'll define using formal sums can be defined using vectors. But it's traditional to
represent polynomials as formal sums, so this is what I'll do.
A nonzero polynomial  has degree n if  and  , and n is the largest integer with this
property. The zero polynomial is defined by convention to have degree  . (This is necessary in order to
make the dgree formulas work out.) Alternatively, you can say that the degree of the zero polynomial is
undefined; in that case, you will need to make minor changes to some of the results below.
Polynomials are added componentwise, and multiplied using the "convolution" formula:
These formulas say that you compute sums and products as usual.
Example. ( Polynomial arithmetic) In  ,
Let R be an integral domain. Then If  , write  to denote the degree of f. It's easy to show that the
degree function satisfies the following properties:
The verifications amount to writing out the formal sums, with a little attention paid to the case of the zero
polynomial. These formulas {\it do} work if either f or g is equal to the zero polynomial, provided that  is
understood to behave in the obvious ways (e.g.  for any  ).
Example. ( Degrees of polynomials) Note that in  ,
This shows that equality might not hold in  .
The equality  might not hold if R is not an integral domain. For example, take 
 . Then (since  ),
Lemma. Let F be a field, and let  be the polynomial ring in one variable over F. The units in  are
exactly the nonzero elements of F.
Proof. It's clear that the nonzero elements of F are invertible in  , since they're already invertible in F.
Conversely, suppose that  is invertible, so  for some  . Then 
 , which is impossible unless f and g both have degree 0. In particular, f is a nonzero
constant, i.e. an element of F.
Theorem. ( Division Algorithm) Let F be a field, and let  . Suppose that  . There exist 
 such that
Proof. The idea is to imitate the proof of the Division Algorithm for  .
Let
The set  is a subset of the nonnegative integers, and therefore must contain a smallest
element by well-ordering. Let  be an element in S of smallest degree, and write
I need to show that  .
If  , then since  ,  .
Suppose then that  . Assume toward a contradiction that  . Write
Assume  , and  .
Consider the polynomial
Its degree is less than n, since the n-th degree terms cancel out.
However,
The latter is an element of S.
I've found an element of S of smaller degree than  , which is a contradiction. It follows that 
 , and this completes the proof.
Page 4


Polynomial Rings
If R is a ring, then  , the ring of polynomials in x with coefficients in R, consists of all formal sums 
 , where  for all but finitely many values of i.
If  is a nonzero polynomial, the degree is the largest  such that  . The zero
polynomial has degree  .
 becomes a ring with the usual operations of polynomial addition and multiplication.
If F is a field, the units in  are exactly the nonzero elements of F.
If  is a field,  , and  , there are unique polynomials  such
that
Let R be an integral domain. An element  is irreducible if  , x is not a unit, and if 
implies either y is a unit or z is a unit.
Let R be an integral domain. An element  is prime if  , x is not a unit, and  implies 
 or  .
In an integral domain, primes are irreducible.
Let F be a field. If  are not both zero, then  and  have a greatest common
divisor which is unique up to multiplication by units (elements of F).
Let F be a field, let  , and let  be a greatest common divisor of  and  .
There are polynomials  such that
If R is a ring, the ring of polynomials in x with coefficients in R is denoted  . It consists of all formal
sums
Here  for all but finitely many values of i.
If the idea of "formal sums" worries you, replace a formal sum with the infinite vector whose components are
the coefficients of the sum:
All of the operations which I'll define using formal sums can be defined using vectors. But it's traditional to
represent polynomials as formal sums, so this is what I'll do.
A nonzero polynomial  has degree n if  and  , and n is the largest integer with this
property. The zero polynomial is defined by convention to have degree  . (This is necessary in order to
make the dgree formulas work out.) Alternatively, you can say that the degree of the zero polynomial is
undefined; in that case, you will need to make minor changes to some of the results below.
Polynomials are added componentwise, and multiplied using the "convolution" formula:
These formulas say that you compute sums and products as usual.
Example. ( Polynomial arithmetic) In  ,
Let R be an integral domain. Then If  , write  to denote the degree of f. It's easy to show that the
degree function satisfies the following properties:
The verifications amount to writing out the formal sums, with a little attention paid to the case of the zero
polynomial. These formulas {\it do} work if either f or g is equal to the zero polynomial, provided that  is
understood to behave in the obvious ways (e.g.  for any  ).
Example. ( Degrees of polynomials) Note that in  ,
This shows that equality might not hold in  .
The equality  might not hold if R is not an integral domain. For example, take 
 . Then (since  ),
Lemma. Let F be a field, and let  be the polynomial ring in one variable over F. The units in  are
exactly the nonzero elements of F.
Proof. It's clear that the nonzero elements of F are invertible in  , since they're already invertible in F.
Conversely, suppose that  is invertible, so  for some  . Then 
 , which is impossible unless f and g both have degree 0. In particular, f is a nonzero
constant, i.e. an element of F.
Theorem. ( Division Algorithm) Let F be a field, and let  . Suppose that  . There exist 
 such that
Proof. The idea is to imitate the proof of the Division Algorithm for  .
Let
The set  is a subset of the nonnegative integers, and therefore must contain a smallest
element by well-ordering. Let  be an element in S of smallest degree, and write
I need to show that  .
If  , then since  ,  .
Suppose then that  . Assume toward a contradiction that  . Write
Assume  , and  .
Consider the polynomial
Its degree is less than n, since the n-th degree terms cancel out.
However,
The latter is an element of S.
I've found an element of S of smaller degree than  , which is a contradiction. It follows that 
 , and this completes the proof.
Example. ( Polynomial division) Division of polynomials should be familiar to you --- at least over  and 
.
In this example, I'll divide  by  in  . Remember as you follow the division that 
 ,  , and  --- I'm doing arithmetic mod 5.
If you prefer, you can do long division without writing the powers of x --- i.e. just writing down the coefficients.
Here's how it looks:
Either way, the quotient is  and the remainder is  :
Definition. Let R be a commutative ring and let  . An element  is a root of  if 
.
Note that polynomials are actually formal sums, not functions. However, it is obvious how to plug a number into
a polynomial. Specifically, let
For  , define
Observe that a polynomial can be nonzero as a polynomial even if it equals 0 for every input! For example,
take  is a nonzero polynomial. However, plugging in the two elements of the coefficient
ring  gives
Page 5


Polynomial Rings
If R is a ring, then  , the ring of polynomials in x with coefficients in R, consists of all formal sums 
 , where  for all but finitely many values of i.
If  is a nonzero polynomial, the degree is the largest  such that  . The zero
polynomial has degree  .
 becomes a ring with the usual operations of polynomial addition and multiplication.
If F is a field, the units in  are exactly the nonzero elements of F.
If  is a field,  , and  , there are unique polynomials  such
that
Let R be an integral domain. An element  is irreducible if  , x is not a unit, and if 
implies either y is a unit or z is a unit.
Let R be an integral domain. An element  is prime if  , x is not a unit, and  implies 
 or  .
In an integral domain, primes are irreducible.
Let F be a field. If  are not both zero, then  and  have a greatest common
divisor which is unique up to multiplication by units (elements of F).
Let F be a field, let  , and let  be a greatest common divisor of  and  .
There are polynomials  such that
If R is a ring, the ring of polynomials in x with coefficients in R is denoted  . It consists of all formal
sums
Here  for all but finitely many values of i.
If the idea of "formal sums" worries you, replace a formal sum with the infinite vector whose components are
the coefficients of the sum:
All of the operations which I'll define using formal sums can be defined using vectors. But it's traditional to
represent polynomials as formal sums, so this is what I'll do.
A nonzero polynomial  has degree n if  and  , and n is the largest integer with this
property. The zero polynomial is defined by convention to have degree  . (This is necessary in order to
make the dgree formulas work out.) Alternatively, you can say that the degree of the zero polynomial is
undefined; in that case, you will need to make minor changes to some of the results below.
Polynomials are added componentwise, and multiplied using the "convolution" formula:
These formulas say that you compute sums and products as usual.
Example. ( Polynomial arithmetic) In  ,
Let R be an integral domain. Then If  , write  to denote the degree of f. It's easy to show that the
degree function satisfies the following properties:
The verifications amount to writing out the formal sums, with a little attention paid to the case of the zero
polynomial. These formulas {\it do} work if either f or g is equal to the zero polynomial, provided that  is
understood to behave in the obvious ways (e.g.  for any  ).
Example. ( Degrees of polynomials) Note that in  ,
This shows that equality might not hold in  .
The equality  might not hold if R is not an integral domain. For example, take 
 . Then (since  ),
Lemma. Let F be a field, and let  be the polynomial ring in one variable over F. The units in  are
exactly the nonzero elements of F.
Proof. It's clear that the nonzero elements of F are invertible in  , since they're already invertible in F.
Conversely, suppose that  is invertible, so  for some  . Then 
 , which is impossible unless f and g both have degree 0. In particular, f is a nonzero
constant, i.e. an element of F.
Theorem. ( Division Algorithm) Let F be a field, and let  . Suppose that  . There exist 
 such that
Proof. The idea is to imitate the proof of the Division Algorithm for  .
Let
The set  is a subset of the nonnegative integers, and therefore must contain a smallest
element by well-ordering. Let  be an element in S of smallest degree, and write
I need to show that  .
If  , then since  ,  .
Suppose then that  . Assume toward a contradiction that  . Write
Assume  , and  .
Consider the polynomial
Its degree is less than n, since the n-th degree terms cancel out.
However,
The latter is an element of S.
I've found an element of S of smaller degree than  , which is a contradiction. It follows that 
 , and this completes the proof.
Example. ( Polynomial division) Division of polynomials should be familiar to you --- at least over  and 
.
In this example, I'll divide  by  in  . Remember as you follow the division that 
 ,  , and  --- I'm doing arithmetic mod 5.
If you prefer, you can do long division without writing the powers of x --- i.e. just writing down the coefficients.
Here's how it looks:
Either way, the quotient is  and the remainder is  :
Definition. Let R be a commutative ring and let  . An element  is a root of  if 
.
Note that polynomials are actually formal sums, not functions. However, it is obvious how to plug a number into
a polynomial. Specifically, let
For  , define
Observe that a polynomial can be nonzero as a polynomial even if it equals 0 for every input! For example,
take  is a nonzero polynomial. However, plugging in the two elements of the coefficient
ring  gives
Corollary. Let F be a field, and let  , where  .
(a) ( The Root Theorem) c is a root of  in F if and only if  .
(b)  has at most n roots in F.
Proof. (a) Suppose  . Write
Then  or  .
In the first case, r is a nonzero constant. However, this implies that
This contradiction shows that  , and  .
Conversely, if  is a factor of  , then  for some  . Hence,
and c is a root of f.
(b) If  are the distinct roots of f in F, then
Taking degrees on both sides gives  .
Example. ( Applying the Root Theorem) Consider polynomials in  .
If  , it's obvious that  is a root. Therefore,  is a factor of  .
Likewise,  must be a factor of  for any  , since  is a root of  .
Example. ( Applying the Root Theorem) Prove that  is divisible by  in  .
Plugging in  gives
Since  is a root,  is a factor, by the Root Theorem.
Example. ( A polynomial with more roots than its degree) The quadratic polynomial 
 has roots  ,  ,  ,  . The previous result does not apply, because 
 is not a field.
On the other hand,  has at most 3 roots over  , since  is a field. (In fact, this polynomial has no
roots in  , as you can verify by plugging in 0, 1, 2, 3, and 4.
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FAQs on Polynomial Rings and Irreducibility Criteria - Ring Theory, CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is a polynomial ring?
Ans. A polynomial ring is a commutative ring formed by polynomials with coefficients in a given ring. In other words, it is the set of all polynomials with coefficients from a given ring, along with the usual operations of addition and multiplication.
2. What are irreducibility criteria for polynomials?
Ans. Irreducibility criteria are conditions or tests used to determine whether a polynomial can be factored further into irreducible polynomials or not. Some commonly used criteria include Eisenstein's criterion, the rational root theorem, and the reducibility criterion for quadratic polynomials.
3. What is Eisenstein's criterion?
Ans. Eisenstein's criterion is an irreducibility criterion for polynomials that states that if a polynomial has integer coefficients and there exists a prime number that divides all coefficients except the leading coefficient, and the prime squared does not divide the constant term, then the polynomial is irreducible over the rational numbers.
4. What is the rational root theorem?
Ans. The rational root theorem is an irreducibility criterion for polynomials that helps in finding the rational roots of a polynomial with integer coefficients. It states that if a polynomial has a rational root p/q, where p and q are coprime integers, then p must divide the constant term and q must divide the leading coefficient.
5. Can a polynomial with degree 1 be irreducible?
Ans. No, a polynomial with degree 1 cannot be irreducible. A polynomial of degree 1 is in the form of ax + b, where a and b are coefficients. Since this polynomial can be factored as (a)(x) + (b), it is reducible and not irreducible. Irreducible polynomials are those that cannot be factored further into polynomials of lower degree.
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