A discrete form of the theorem that each field endomorphism of R (Qp) is the identity
Abstract
Let K be a field and F denote the prime field in K. Let K denote the set of all r ∈ K for which there exists a finite set A(r) with r ⊂eq A(r) ⊂eq K such that each mapping f:A(r) K that satisfies: if 1 ∈ A(r) then f(1)=1, if a,b ∈ A(r) and a+b ∈ A(r) then f(a+b)=f(a)+f(b), if a,b ∈ A(r) and a · b ∈ A(r) then f(a · b)=f(a) · f(b), satisfies also f(r)=r. Obviously, each field endomorphism of K is the identity on K. We prove: K is a countable subfield of K, if char(K) ≠ 0 then K=F, C=Q, if each element of K is algebraic over F=Q then K=x ∈ K: x is fixed for all automorphisms of K, R is equal to the field of real algebraic numbers, Qp=x ∈ Qp: x is algebraic over Q.
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