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

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In summary, the conversation discusses the possibility of turning R^n into a field for n>2. It is stated that for n=1 and n=2, it is possible as they are isomorphic to the complex plane. However, for n>2, there is no known way to define invertible, closed multiplication and division operations. It is mentioned that for dimensions three or higher, it is a proven theorem that R^n cannot be turned into a field. The explanation for this uses elementary methods and should be easily found. There is a technical issue with the statement and it is suggested to instead say that if F is a field in the category of real vector spaces, then F has dimension 1 or 2.
  • #1
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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  • #2
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).
 
  • #3
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.
 
  • #4
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.
 

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

What is R^n?

R^n refers to the set of n-dimensional real numbers, including all possible combinations of n real numbers.

What does it mean for R^n to be a field?

A field is a mathematical structure that satisfies specific properties, including the existence of addition, subtraction, multiplication, and division operations that follow certain rules. In the case of R^n, these operations are defined for n-dimensional real numbers.

How is R^n different from R^2 or R^3?

R^n encompasses all possible combinations of n real numbers, while R^2 and R^3 only include combinations of 2 and 3 real numbers, respectively. R^n is a more general and abstract concept compared to R^2 and R^3.

Why is it important to prove that R^n can be a field for n>2?

Proving that R^n can be a field for n>2 is important because it expands our understanding of the properties of fields beyond the traditional 2 or 3 dimensions. This proof can also have implications in other areas of mathematics, such as abstract algebra and topology.

What is the significance of this proof in the field of mathematics?

This proof is significant in the field of mathematics because it provides a deeper understanding of the properties and structure of fields, which have applications in many areas of mathematics and other scientific fields. It also highlights the power and importance of abstract mathematical thinking and proofs.

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