How to show two rings are not isomorphic

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Discussion Overview

The discussion revolves around methods to demonstrate that two rings, specifically 2Z and 3Z, are not isomorphic. Participants explore various approaches, including properties of abelian groups, multiplicative structures, and specific isomorphisms.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Mathematical reasoning

Main Points Raised

  • One participant notes that if the associated abelian groups of two rings are isomorphic, it does not guarantee that the rings themselves are isomorphic.
  • Another suggests examining the quotient rings Z/2Z and Z/3Z to argue that if 2Z and 3Z were isomorphic, then these quotient rings should also be isomorphic.
  • A participant proposes using a specific isomorphism and properties of ring operations to derive a contradiction, indicating that the multiplicative structure fails under the assumed isomorphism.
  • Some participants emphasize the need to check both addition and multiplication properties when considering ring isomorphisms.
  • There is a discussion about the validity of reasoning that connects the isomorphism of 2Z and 3Z to the isomorphism of their respective quotient rings, with one participant questioning this logic.
  • Another participant points out that simply showing one isomorphism fails does not suffice to conclude that the rings are not isomorphic, suggesting a more general argument is needed.
  • One participant mentions looking at the invertible elements of the rings as a potential method to show non-isomorphism.
  • There is a claim that 2Z and 3Z are isomorphic as rings, which contradicts earlier claims, leading to confusion and further debate.

Areas of Agreement / Disagreement

Participants express differing views on the validity of certain arguments, particularly regarding the relationship between the isomorphism of rings and their associated abelian groups. There is no consensus on the methods to conclusively show that 2Z and 3Z are not isomorphic, and some participants assert conflicting positions regarding their isomorphism.

Contextual Notes

Some arguments rely on specific properties of isomorphisms and the structure of rings, but the discussion reveals limitations in the reasoning presented, particularly concerning the assumptions made about isomorphisms and the properties of the rings involved.

samkolb
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I'm just beginning my study of rings, and I'm wondering if there are some standard ways to show that two rings are not isomorphic. I've studied groups quite a bit and I know some of the ways to show that two groups are not isomorphic (G contains an element of order 2 while G' contains no element of order 2, etc...).

In particular, if for two rings R and R' their associated abelian groups A and A' are isomorphic, what are some ways to use the multiplicative properties of R and R' to show that R and R' are not isomprhic?

The problem I'm working on is to show that the rings 2Z and 3Z are not isomorphic.
 
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Here, 2Z and 3Z are both subrings of Z. You could look at Z/2Z and Z/3Z. If 2Z and 3Z were isomorphic, then Z/2Z and Z/3Z should be isomorphic as well.
 
Suppose
2Z~3Z
with f an isomorphism and
f(2)=3k k in Z
2+2=2*2
f(2+2)=f(2*2)
use the properties of f and Z to arrive at a contradiction
 
Consider the isomorphism that relates 2Z and 3Z as abelian groups (or nZ for any integer n). As groups, these structures are isomorphic. In order to be isomorphic as rings, the homomorphism property must be satisfied for addition and multiplication. We know that addition works, and we need to check multiplication. Use the same isomorphism you used under addition, and you will see that it fails with multiplication.
 
joecoz88 said:
Consider the isomorphism that relates 2Z and 3Z as abelian groups (or nZ for any integer n). As groups, these structures are isomorphic. In order to be isomorphic as rings, the homomorphism property must be satisfied for addition and multiplication. We know that addition works, and we need to check multiplication. Use the same isomorphism you used under addition, and you will see that it fails with multiplication.

That alone doesn't solve it; you only showed that one particular group isomorphism isn't a ring isomorphism. You need to explain why there is no group isomorphism that is a ring isomorphism. (Then again, there are only two group isomorphisms, and it's easy to check both.)

lurflurf gives a simple solution with a concrete example, and quasar987 gives a more abstract one (but nicer).
 
Yes I see that my solution wasn't general enough, thanks for the correction.

But I am having trouble following quasars logic, maybe someone could elaborate?

I can't see the reason why if 2Z and 3Z are isomorphic, then Z/2Z and Z/3Z should be isomorphic? Is this reasoning valid?

As groups we can see that 2Z and 3Z are isomorphic, but Z/2Z and Z/3Z are not isomorphic.
 
Well, uh,

good point! :) No, it's not valid, and silly me. And bad quasar. :)
 
Last edited:
lurflurf's explanation does not describe a specific isomorphism. I agree that picking a function and showing that it is not a ring isomorphism is insufficient to show that two rings are not isomorphic; however, lurflurf's explanation simply made use of the fact that for any function f: A->B, if x belongs to A then f(x) belongs to B. In this example, A=2Z and B=3Z, so if f is an isomorphism from A to B, f(2) belongs to 3Z and thus is of the form 3k for some integer k. lurflurf's other remarks can then be used to show that 2Z and 3Z are not isomorphic, as f was chosen arbitrarily and the description of f(2) came from the description of the codomain of f.
 
A first way for that is to look the invertible elements of the rings .
 
  • #10
placemat said:
lurflurf's other remarks can then be used to show that 2Z and 3Z are not isomorphic


But they are isomorhpic, as rings, with the map 2-->3 (and they're just isomorphic to Z).
 
  • #11
The map that matt shows it not a ring isomorphism, for the exact reason that lurflurf gave: f(2 + 2) = f(2*2) which will contradict any isomorphism between the two structures.
 
  • #12
Doh, being stupid again, sorry.
 

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