If $\phi:\mathbb{Q}(a_1\ldots,a_n)\rightarrow\mathbb{Q}(b_1,\ldots,b_n)$ is an isomorphism of finite extensions of $\mathbb{Q}$ such that $\phi(a_i)=b_i$, can one extend $\phi$ to an automorphism $\sigma$ of the composite $\mathbb{Q}(a_1,\ldots,a_n,b_1,\ldots,b_n)$? Is ther an obvious counter-example?
Automorphisms of composite fields of finite extensions
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0Of course, when talking about extensions of $\bf Q$ of transcendence degree not greater than $\mathfrak c$, $\bf C$ certainly does fit the description of fixed algebraically closed extension of large transcendence degree. :) – 2012-12-08
1 Answers
I've not found a definite answer yet, but here are some partial results. I can't guarantee that I have not overthought it and that there is a much simpler solution. :)
Note that by Abel's theorem on primitive element there is an $\alpha$ such that ${\bf Q}(a_1,\ldots,a_n)={\bf Q}[\alpha]$. In this case, it will also be true that ${\bf Q}[\phi(\alpha)]={\bf Q}(b_1,\ldots,b_n)$ (because $\phi$ is an isomorphism) and $\alpha$ and $\phi(\alpha)$ are conjugate.
Consider $K$, the splitting field of $\alpha$'s minimal polynomial $f_\alpha$. What you ask is equivalent to asking if there's an automorphism $\Phi$ of $K$ such that $\Phi(\alpha)=\phi(\alpha)$, and such that $\Phi(\Phi(\alpha))\in{\bf Q}[\alpha,\phi(\alpha)]$.
This is true, for example, if $\alpha$ and $\phi(\alpha)$ already generate $K$ (e.g. if $\alpha$ is a root of unity, or $\alpha=\sqrt[4]{2},\phi(\alpha)=i\sqrt[4]{2}$, or if $K$ is of prime degree), or if $\phi$ is the restriction of an involutive automorphism (e.g. if $\alpha$ and $\phi(\alpha)$ are complex conjugate), it's also true if the degree of $K$ is the product of at most two (maybe not distinct) primes (so in particular if $f_\alpha$ is at most cubic), and also if the Galois group of $K$ is bitransitive (in particular, if it is the full symmetric group, which I think is the "generic" situation), but I don't think it has to be the case.
Ideally, a counterexample would have $K$ of degree $24$ (anything less won't work, as pointed out by Hurkyl), with $f_\alpha$ of degree $4$. But then the Galois group is the full permutation group, so there's no counterexample with $f_\alpha$ of degree four. This does seem to make the hypothesis viable... but hypotheses that fail only for polynomials of degree five or more are not unheard of. ;)
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0@Hurkyl: good point. :) – 2012-12-07