Rings and fields

Rings and fields

INTRODUCTION • We have studied groups, which is an algebraic structure equipped with one binary operation. Now we shall study rings which is an algebraic structure equipped with two binary operations.

Rings DEFINITION:A non-empty set R equipped with two binary operations called addition and multiplication denoted by (+) and (.) is said to form a ring if the following properties are satisfied: 1. R is closed w.r.t. addition i.e. a,b ∈ R, then a+b ∈ R 2. Addition is associative i.e. (a+b)+c=a+(b+c) for all a, b, c ∈ R 3. Addition is commutative i. e. a+b=b+a for all a,b ∈ R

4. Existence of additive identity i.e. there exists an additive identity in R denoted by 0 in R such that 0+a=a=a+0 for all a ∈ R 5.Existence of additive inverse i.e. to each element a in R, there exists an element –a in R such that -a+a=0=a+(-a) 6. R is closed w.r.t. multiplication i.e. if a,b ∈ R, then a.b ∈ R

7. Multiplication is associative i.e. a.(b.c)=(a.b).c for all a,b,c ∈ R 8.Multiplication is associative i.e. for all a,b,c in R a.(b+c)=a.b+a.c [left distribution law] And (b+c).a=b.a+c.a [right distribution law] REMARK: any algebraic structure (R, + , . ) is called a ring if (R,+) is an abelian group and the properties 6, 7, 8 given above also satisfied.

TYPES OF RINGS 1. Commutative ring: a ring in which a.b=b.a for all a,b ∈ R is called commutative ring. 2. Ring with unity: if in a ring, there exists an element denoted by 1 such that 1.a=a=a.1 for all a ∈ R , then R is called ring with unit element. The element 1 ∈ R is called the unit element of the ring.

3. Null ring or zero ring: The set R consisting of a single element 0 with two binary operations denoted by 0+0=0 and 0.0=0 is a ring and is called null ring or zero ring.

Example of Ring • Prove that the set Z of all integers is a ring w.r.t. the addition and multiplication of integers as the two ring compositions. Solution: Properties under addition; • Closure property: As sum of two integers is also an integer, therefore Z is closed w.r.t. addition of integers. • Associativity: As addition of integers is an associative composition therefore a+(b+c)=(a+b)+c for all a,b,c ∈ Z

3. Existenceof additive identity: for 0 ∈ Z , 0+a=a=a+0 for all a ∈ Z Therefore 0 is the additive identity. 4. Existence of additive inverse: for each a ∈ Z, there exists -a ∈ Z such that a+(-a)=0=(-a)+a Where 0 is the identity element. 5. Commutative property: a+b=b+a for all a,b ∈ Z

Properties under multiplication: 6. Closure property w.r.t. multiplication: as product of two integers is also an integer Therefore a.b ∈ Z for all a,b ∈ Z 7.Multiplication is associative: a.(b.c)=(a.b).c for all a,b,c ∈ Z 8. Multiplication is distributive w.r.t. addition: For all a,b,c ∈ Z, a.(b+c)=a.b+a.c And (b+c).a=b.a+c.a Hence Z is a ring w.r.t. addition and multiplication of integers.

RING WITHOUT OR WITH ZERO DIVISOR , INTEGER DOMAIN , DIVISION RING

Definition • A ring (R, +, .) is said to be without zero divisor if for all a, b ∈ R a.b=0 => either a=0 or b=0 On the other hand, if in a ring R there exists non-zero elements a and b such that a.b=0, then R is said to be a ring with zero divisors.

EXAMPLES • Sets Z , Q , R and C are without zero divisors if for all a,b∈ R • The ring ({0 , 1 , 2 , 3 , 4 , 5} , +6 , *6 ) is a ring with zero divisors.

INTEGER DOMAIN Definition: a commutative ring without zero divisors, having atleast two elements is called an integer domain. For example, algebraic structures (Z , +, .), (Q , + ,.), (R, + , .),(C , + , .) are all integral domains.

Division ring or skew field • Definition: a ring is said to be a division ring or skew field if its non-zero elements forms a group under multiplication.

Field • A field is a commutative division ring. • Another definition: let F be a non empty set with atleast two elements and equipped with two binary operations defined by (+) , (.) respectively. Then the algebraic structure (F, +, .) is a field if the following properties are satisfied: axioms of addition: 1. Closure property: a+b∈ F for all a,b∈ F

2. Associative law: a+(b+c)=(a+b)+c for all a,b,c∈ F 3. Existence of identity: for all a∈ F, there exists an element 0 ∈ F such that a+0=a=0+a 4. Existence of inverse: for each a ∈ F, there exists an element b ∈ F such that a+b=0=b+a Element b is called inverse of a and is denpted by –a.

Commutative law: a+b=b+a for all a, b ∈ F Axioms of multiplication: 6. Closure law: for all a,b ∈ F , the element of a.b∈ F 7. Commutative law: a.b=b.a for all a,b ∈ F 8. Associative law: multiplication is associative i.e., (a.b).c=a.(b.c) for all a,b,c ∈ F 9. Existence of multiplication identity: for each a ∈ F, there exists 1 ∈ F such that a.1=1.a=a

10. Existence of inverse: for each non-zero element a ∈ F, there exists an element b ∈ F such that a.b=b.a=1 element b is called multiplicative inverse of a and is denoted by 1/a. 11. Distributive law: multiplication is distributive w.r.t. addititon i.e., for all a,b,c ∈ F a.(b+c)=a.b+a.c (b+c).a=b.a+c.a

THEOREM: A commutative ring is an integer domain if and only if cancellation law holds in the ring • Proof: let R be a commutative ring. Suppose R is an integeral domain. We have to prove that cancellation law holds in R. let a, b, c ∈ R and a≠ 0 such that ab=ac • ab-ac=0 • a(b-c)=0 Since R is an integral domain, so R is without zero divisors.

Therefore either a=0 or b-c=0 Since a≠0 so b-c=0 => b=c Hence, cancellation law holds in R. Conversely, suppose that cancellation law holds in R. Now, we have to prove that R is an integral domain. As R is commutative so we only have to show that R is without zero divisors.

If a=0, then we have nothing to prove. If a≠0 then ab=0=a.0 • b=0 • R is without zero divisors. Hence R is an integral domain.

SUBRINGS

Definition Subrings: If R is a ring under two binary compositions and S is a non-empty subset of R such that S itself is a ring under the same binary operations, then S is called subring of R.

Examples of subrings • Z is a subring of the ring (Q , + , . ) • Q is a subring of the ring ( R , + , . ) • {0} and R are always subrings of the ring R and are called improper subrings of R . Other subrings if any, are called proper subrings of R.

Theorem: The necessary and sufficient conditions for a non-empty subset S of the ring R to be a subring of R are(i) a,b ∈ S => a-b ∈ S(ii) a,b ∈ S => a.b ∈ S Proof: Conditions are necessary: Suppose ( S, +, .) is a subring of (R, +, .) Let a,b ∈ S => -b ∈ S [Since –b is additive inverse of b]

a-b ∈ S [since S is closed w.r.t. addition] Also a.b ∈ S [since S is closed w.r.t multiplication] Hence, a,b ∈ S => a-b ∈ S and a.b ∈ S Conditions are sufficient: Suppose S is a non-empty subset of R such that for all a,b ∈ S, a-b ∈ S and a.b ∈ S Now a ∈ S, a ∈ S => a-a ∈ S => 0 ∈ S

Therefore additive identity exists. 0 ∈ S, a ∈ S => 0-a= -a ∈ S i.e., each element of S possesses additive inverse. a∈ S, -b ∈ S, => a-(-b)=a+b ∈ S Thus S is closed w.r.t. addition. As S is a subset of R , therefore associativity an commutativity must hold in S as they hold in R. Now, a,b ∈ S => a.b∈ S

Therefore S is closed w.r.t. multiplication As S is a subset of R, therefore associativity of multiplication and distributive laws must hold n S as they hold in R. Hence S is a subring of R.

Theorem: The intersection of two subrings is a subring. • Proof: let S1 and S2 be two subrings of R. As additive identity 0 is common element of S1 and S2. Therefore S1 ∩ S2 ≠  To show that S1 ∩ S2 is a subring, it is sufficient to prove that • a,b ∈ S1 ∩ S2 => a-b ∈ S1 ∩ S2 • a,b ∈ S1 ∩ S2 => a.b ∈ S1 ∩ S2 let a,b be any two elements of S1 ∩ S2

a,b ∈ S1 and a,b ∈ S2 Since S1 and S2 are subrings Therefore a-b ∈ S1 and a-b ∈ S2 a.b ∈ S1 and a.b ∈ S2 • a-b ∈ S1 ∩ S2 and a.b ∈ S1 ∩ S2 Hence S1 ∩ S2is a subring of R.

Example: prove that the set of integers is a subring of ring of rational numbers. Solution: let Z be the set of integers and Q be the ring of rationals. Therefore Z is a subset of Q. 0 ∈ Z => Z≠  Let a,b be any two elements of Z. Therefore a-b∈Z and ab ∈ Z Hence Z is a subring of Q.

Assignment • Define ring and its types. • Prove that the set Z of all integers is a ring w.r.t. the addition and multiplication of integers as the two ring cmpositions. • Define field. A commutative ring is an integer domain if and only if cancellation law holds in the ring . • Define sub-ring. The necessary and sufficient conditions for a non-empty subset S of the ring R to be a subring of R are

Assignment • a,b ∈ S => a-b ∈ S • a,b ∈ S => a.b ∈ S 5. Prove that The intersection of two subrings is subring. 6. Prove that the set of integers is a subring of ring of rational numbers.

Test • Do any two questions: • Prove that the set Z of all integers is a ring w.r.t. the addition and multiplication of integers as the two ring cmpositions. • Define sub-ring. The necessary and sufficient conditions for a non-empty subset S of the ring R to be a subring of R are • a,b ∈ S => a-b ∈ S • a,b ∈ S => a.b ∈ S

Test 3. . Prove that The intersection of two subrings is subring.

Rings and fields

Rings and fields

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