An MSc student asked me if I knew an example of a prime $p$ and some finite layer $K_n$ in the cyclotomic $\mathbf{Z}_p$-extension of $\mathbf{Q}$ (so $[K_n:\mathbf{Q}]=p^n$) which had non-trivial class group. My gut feeling was that fixing a $p$ and then going up the tower was a bad idea in the sense that going along might find a counterexample quicker, so I tried going along instead, but my computer is having trouble looking at the bottom level when $p$ starts getting bigger than about 30. So now I'm just confused. Presumably this question has been raised before? Can anyone enlighten me with a counterexample or reassurance that this is a standard open question?
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asked Dec 2, 2011 at 16:21
1 Answer
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I found the notes of Coates' seminar I alluded to in my comment above. He said the following:
For $n \ge 1$, let $h(n)$ denote the class number of the unique cyclic degree $n$ extension contained in the compositum of all the cyclotomic $\mathbb{Z}_p$-extensions for $p \mid n$. It is apparently not too difficult to show that if $n \mid m$, then $h(n) \mid h(m)$, and that if $n$ is a power of $p$, then $h(n)$ is prime to $p$.
Then Weber (not Kronecker, but close!) has conjectured that $h(2^n) = 1$ for all $n$, and this is known for $n \le 5$ and for $n=6$ conditional on GRH. More generally, it is a folklore conjecture that $h(n) = 1$ for all prime power values of $n$.
Horie, Fukuda and Komatsu have recently shown that $h(62)$ is divisible by 31, the first known example of an integer $n$ where $h(n) > 1$.
So the verdict seems to be that your student's question is a well-known open problem.
answered Dec 2, 2011 at 17:07
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$\begingroup$ This is very interesting, but I don't see the conclusion that "your student's question is a well-known open problem". You only talk about $K_1$'s (for various primes $p$) and their compositums. Sorry if I am missing something, I am no expert as I said. $\endgroup$ Commented Dec 2, 2011 at 17:18
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$\begingroup$ @GH: You misunderstand. Coates' $h(p^n)$ is the class number of the $n$th layer in the cyclotomic $\mathbb{Z}_p$-extension. $\endgroup$ Commented Dec 2, 2011 at 17:47
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1$\begingroup$ Coates also spoken about this in his Part III course this term. In recent work (jtnb.cedram.org/item?id=JTNB_2010__22_2_359_0 ) Fukuda and Komatsu show that if a prime p divides $h(2^n)$ for some $n$ then $p > 1.2 \times 10^8$ and $p \not \equiv \pm 1 \mod 16$. $\endgroup$ Commented Dec 2, 2011 at 18:01
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2$\begingroup$ Folks, please look at the comments to Cam's answer at mathoverflow.net/questions/41219/…. $\endgroup$– KConradCommented Dec 3, 2011 at 3:31
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2$\begingroup$ Newsflash: at arxiv.org/pdf/1405.1094v1.pdf John Miller has announced a proof that $h(2^n) = 1$ for $n = 6$ (that is, the real cyclotomic field ${\mathbf Q}(\zeta_{128})^+$ has class number 1) and under GRH it's true for $n = 7$. $\endgroup$– KConradCommented May 7, 2014 at 3:06
$K_n=\mathbf{Q}(\zeta+\zeta^a+\zeta^{a^2}+\dots+\zeta^{a^{p-2}})$where $\zeta$ is a primitive $p^{n+1}$st root of unity. $\endgroup$