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=[[HW7_MA453Fall2008walther|HW7]] (Chapter 13, Problem 28, [[MA453]], Fall 2008, [[user:walther|Prof. Walther]]=
 
=[[HW7_MA453Fall2008walther|HW7]] (Chapter 13, Problem 28, [[MA453]], Fall 2008, [[user:walther|Prof. Walther]]=
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==Question==
 
Prove that there is no integral domain with exactly six elements
 
Prove that there is no integral domain with exactly six elements
 
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I have no idea where to begin on this problem. I do not know how to prove that there is no integral domain with six elements. A little help would be nice. Thanks
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==Discussion==
  
Begin by saying that R is the domain with exactly 6 elements (order of 6). The characteristic of an integral domain is zero or prime, and 6 is the smallest possible integer such that 6*1 = 0 in mod6. Therefore there can not be an integral domain with exactly six elements.  
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*I have no idea where to begin on this problem. I do not know how to prove that there is no integral domain with six elements. A little help would be nice. Thanks
Pf:
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(Char(R))= prime
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Char(R) = 2, 3, 5 (it is a subgroup of the domain)
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(R, +) is an Abelian Group
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By Lagraunge theorem, the subgroup must be a divisor of the large group so
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*Begin by saying that R is the domain with exactly 6 elements (order of 6). The characteristic of an integral domain is zero or prime, and 6 is the smallest possible integer such that 6*1 = 0 in mod6. Therefore there can not be an integral domain with exactly six elements.
n/6 therefore n must equal either 2 or 3
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::Pf:
If n=3 then the subgroup is {0,1,2} contained in R
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::(Char(R))= prime
Therefore R = Z_3 * H
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::Char(R) = 2, 3, 5 (it is a subgroup of the domain)
This is by a theorem that says that every abelian group with G = p1^a1.....pk^ak where p is prime. G is going to be a product G1 *....Gk where the order of Gi = p1^a1.
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::(R, +) is an Abelian Group
  
Therefore, R = Z_3 X Z_2
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::By Lagrange theorem, the subgroup must be a divisor of the large group so n/6 therefore n must equal either 2 or 3
1 corresponds to (1,0)    a corresponds to (1,1)
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::If n=3 then the subgroup is {0,1,2} contained in R.
2 corresponds to (2,0)    b corresponds to (2,1)
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::Therefore R = Z_3 * H
0 corresponds to (0,0)    c corresponds to (0,1)
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::This is by a theorem that says that every abelian group with G = p1^a1.....pk^ak where p is prime. G is going to be a product G1 *....Gk where the order of Gi = p1^a1.
2 is an element of R, and thus does not equal 0
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R domain therefore 2 is not a zero divisor so by induction 2 is not Z_m
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Continue with same argument for n=2 vise versa....
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::Therefore, R = Z_3 X Z_2
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:::1 corresponds to (1,0)    a corresponds to (1,1)
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:::2 corresponds to (2,0)    b corresponds to (2,1)
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:::0 corresponds to (0,0)    c corresponds to (0,1)
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:::2 is an element of R, and thus does not equal 0
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:::R domain therefore 2 is not a zero divisor so by induction 2 is not Z_m
  
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::Continue with same argument for n=2 vise versa....
  
--[[User:Robertsr|Robertsr]] 19:22, 22 October 2008 (UTC)
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:::--[[User:Robertsr|Robertsr]] 19:22, 22 October 2008 (UTC)
  
  
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*An integral domain is a ring. A ring has the commutative property for addition. There is only one Abelian group with order(number of elements)=p, where p is prime. Z_6 can be written as Z_2 * Z_3 and Z_2 and Z_3 both have prime order. Z_6 therefore is the only Abelian group with 6 elements. So, Z_6 can be the only ring with 6 elements. Z_6 is an integral domain if there are no zerodivisiors. 2*3=0, 2 and 3 are zero divisors. So, Z_6 is not an integral domain. Similary, Z_15= Z_3 * Z_5, so it is the only Abelian group with 15 elements. 3*5=0, there are zerodivisors, it is not an integral domain.
  
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:Try Z_4 = Z_2 * Z_2. There is no zerodivisors, so it is in fact an integral domain. Generally, if the number of elements of a group is the products of different primes, it cannot form an integral domain. However, if the number of elements of a group is the product of the same prime (eg. p^2 or p^3), it can form an integral domain.
  
An integral domain is a ring. A ring has the commutative property for addition.
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::-Ozgur
There is only one Abelian group with order(number of elements)=p, where p is prime. Z_6 can be written as Z_2 * Z_3 and Z_2 and Z_3 both have prime order. Z_6 therefore is the only Abelian group with 6 elements. So, Z_6 can be the only ring with 6 elements. Z_6 is an integral domain if there are no zerodivisiors. 2*3=0, 2 and 3 are zero divisors. So, Z_6 is not an integral domain. Similary, Z_15= Z_3 * Z_5, so it is the only Abelian group with 15 elements. 3*5=0, there are zerodivisors, it is not an integral domain.
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Try Z_4 = Z_2 * Z_2. There is no zerodivisors, so it is in fact an integral domain. Generally, if the number of elements of a group is the products of different primes, it cannot form an integral domain. However, if the number of elements of a group is the product of the same prime (eg. p^2 or p^3), it can form an integral domain.
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-Ozgur
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--[[User:Dakinsey|Dakinsey]] 16:14, 26 October 2008 (UTC)
 
--[[User:Dakinsey|Dakinsey]] 16:14, 26 October 2008 (UTC)
 
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[[HW7_MA453Fall2008walther|Back to HW7]]
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[[Main_Page_MA453Fall2008walther|Back to MA453 Fall 2008]]

Latest revision as of 08:45, 21 March 2013


HW7 (Chapter 13, Problem 28, MA453, Fall 2008, Prof. Walther


Question

Prove that there is no integral domain with exactly six elements


Discussion

  • I have no idea where to begin on this problem. I do not know how to prove that there is no integral domain with six elements. A little help would be nice. Thanks
  • Begin by saying that R is the domain with exactly 6 elements (order of 6). The characteristic of an integral domain is zero or prime, and 6 is the smallest possible integer such that 6*1 = 0 in mod6. Therefore there can not be an integral domain with exactly six elements.
Pf:
(Char(R))= prime
Char(R) = 2, 3, 5 (it is a subgroup of the domain)
(R, +) is an Abelian Group
By Lagrange theorem, the subgroup must be a divisor of the large group so n/6 therefore n must equal either 2 or 3
If n=3 then the subgroup is {0,1,2} contained in R.
Therefore R = Z_3 * H
This is by a theorem that says that every abelian group with G = p1^a1.....pk^ak where p is prime. G is going to be a product G1 *....Gk where the order of Gi = p1^a1.
Therefore, R = Z_3 X Z_2
1 corresponds to (1,0) a corresponds to (1,1)
2 corresponds to (2,0) b corresponds to (2,1)
0 corresponds to (0,0) c corresponds to (0,1)
2 is an element of R, and thus does not equal 0
R domain therefore 2 is not a zero divisor so by induction 2 is not Z_m
Continue with same argument for n=2 vise versa....
--Robertsr 19:22, 22 October 2008 (UTC)


  • An integral domain is a ring. A ring has the commutative property for addition. There is only one Abelian group with order(number of elements)=p, where p is prime. Z_6 can be written as Z_2 * Z_3 and Z_2 and Z_3 both have prime order. Z_6 therefore is the only Abelian group with 6 elements. So, Z_6 can be the only ring with 6 elements. Z_6 is an integral domain if there are no zerodivisiors. 2*3=0, 2 and 3 are zero divisors. So, Z_6 is not an integral domain. Similary, Z_15= Z_3 * Z_5, so it is the only Abelian group with 15 elements. 3*5=0, there are zerodivisors, it is not an integral domain.
Try Z_4 = Z_2 * Z_2. There is no zerodivisors, so it is in fact an integral domain. Generally, if the number of elements of a group is the products of different primes, it cannot form an integral domain. However, if the number of elements of a group is the product of the same prime (eg. p^2 or p^3), it can form an integral domain.
-Ozgur

This helped. Thanks. --Dakinsey 16:14, 26 October 2008 (UTC)


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