Primes in denominators of algebraic numbers
Abstract
Denote the set of algebraic numbers as Q and the set of algebraic integers as Z. For γ∈Q, consider its irreducible polynomial in Z[x], Fγ(x)=anxn+…+a0. Denote e(γ)=(an,an-1,…,a1). Drungilas, Dubickas and Jankauskas show in a recent paper that Z[γ] Q=\α∈Q \p vp(α)<0\⊂eq \p p|e(γ)\\. Given a number field K and γ∈Q, we show that there is a subset X(K,γ)⊂eq Spec(OK), for which OK[γ] K=\α∈ K \p vp(α)<0\⊂eq X(K,γ)\. We prove that OK[γ] K is a principal ideal domain if and only if the primes in X(K,γ) generate the class group of OK. We show that given γ∈ Q, we can find a finite set S⊂eq Z, such that for every number field K, we have X(K,γ)=\p∈Spec(OK) p S≠ \. We study how this set S relates to the ring Z[γ] and the ideal Dγ=\a∈Z aγ∈Z\ of Z. We also show that γ1,γ2∈ Q satisfy Dγ1=Dγ2 if and only if X(K,γ1)=X(K,γ2) for all number fields K.
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