Proving R^n Can Be a Field: The n>2 Case

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Discussion Overview

The discussion centers on whether R^n can be structured as a field for dimensions greater than 2, exploring theoretical aspects and implications of such a structure.

Discussion Character

  • Debate/contested

Main Points Raised

  • One participant questions the possibility of defining an invertible, closed multiplication and division operation for R^n when n>2, suggesting that while R^2 can be represented as the complex plane, R^n for n>2 presents challenges.
  • Another participant asserts that it is a theorem that for dimensions three or higher, Euclidean space cannot be turned into a field, mentioning that there is no field isomorphic to R^n for n≥3.
  • A subsequent reply challenges the assertion made in the previous post, asking for clarification on the category in which the claim is made, suggesting that if F is a field in the category of real vector spaces, then F must have dimension 1 or 2.

Areas of Agreement / Disagreement

Participants express differing views on the possibility of R^n being a field for n>2, with some asserting it is impossible and others questioning the conditions under which this assertion holds.

Contextual Notes

The discussion includes nuances regarding the definitions of fields and vector spaces, as well as the implications of dimensionality on the structure of R^n.

dreamtheater
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Is there a proof that shows if R^n can be turned into a field, for specific n?

Obviously, n=1 is a field, and n=2 can be made into a field (which is just the complex plane.)

So what about n>2?
 
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What invertable, closed, multiplication and division operation are you going to define for n>2?

Even for R^2, your complex numbers, that's a space that's isomorphic with R^2, and is not R^2 itself. You can introduce invertable vector product for R^n (I like the geometric/clifford algebra product for this). But to get invertable and closed with that product you have to combine components of such vector products (ie: complex numbers, and quaternions, or other generalizations of these get by adding grade 0 and 2 components from this larger algebraic space).
 
it is a theorem that for dimensions three or higher euclidean space cannot be turned into a field, or if we want to be pedantic: for n >/= 3 there is no field isomorphic to R^n.

I saw a proof of the fact in a complex analysis class sometime ago so I don't remember it but it uses (very) elementary methods and as such should be found easily.
 
I have a small technical problem with the explanation given in 3: in what sense are you asserting that there are no fields isomorphic to R^n for n>=3? Or more accurately, in what category?

I think that it might be better to say - if F is a field, and F is in VECT(R) - cat of real vector spaces - then F has dimension 1 or 2.
 

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