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There are two approaches to class field theory that I was taught. The first, is the theory of $L$-functions, Dirichlet characters and so forth (which I described succintly in the question What are the pillars of Langlands? that I asked a long time ago), and the other is through Brauer groups.

To be precise, I was taught that the following sketch is class field theory:

Let $K$ be number field. Let $v$ be any non-archimedean place. Then there is some explicit isomorphism $inv_v:Br(K_v)\rightarrow \mathbb{Q}/\mathbb{Z}$. If $v$ is an archimedean place, then there is an explicit isomorphism $inv_v:Br(K_v)\rightarrow \mathbb{Z}/2\mathbb{Z}$ if $K_v$ is $\mathbb{R}$, and $0$ if $K_v$ is $\mathbb{C}$.

Furthermore, the following sequence is exact:

$1\rightarrow Br(K)\rightarrow \bigoplus_v Br(K_v)\rightarrow \mathbb{Q}/\mathbb{Z}\rightarrow 1$

where the first morphism is obvious, and the last morphism is $\sum_v inv_v$.

I take both of these approaches have a lot of content, but it is not clear how people think of them as equivalent. How does one build a dictionary between the one approach and the other?

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  • $\begingroup$ Is is not clear that people think of them as equivalent, IMHO. $\endgroup$
    – Joël
    Commented Oct 31, 2011 at 3:40
  • $\begingroup$ I suppose I have two indications of a connection. The first is the fact that people call both approaches "class field theory". The second is that both generalize quadratic reciprocity (for the second approach, specialize to quaternion algebras of the form $(p,q)$ where $p$ and $q$ are prime). $\endgroup$ Commented Oct 31, 2011 at 3:53
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    $\begingroup$ What you've written out is really only a tiny part of the cohomological approach to class field theory. The rest is described very well by Cassels-Frohlich. $\endgroup$ Commented Oct 31, 2011 at 5:20

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The computation of the Brauer group is only the "first half" of class field theory. The main reason one is interested in the Brauer group is that for a finite Galois extension $L/K$, let's say of local fields, the cup product by a generator of $H^2(G_{L/K},L^\times)$ gives an isomorphism between $G^{ab}(L/K)$ and $K^\times/N_{L/K}L^\times$. This is the reciprocity map, the central part of (local) class field theory. Passing to the limit over all finite Galois extensions gives an isomorphism between $W_K^{ab}$ and $K^\times$, where $W_K$ is the Weil group of $K$. Dualising this establishes a bijection between the one-dimensional representations of $W_K$ (they are one-dimensional, because they are the ones that factor through the abelianisation), and irreducible representations of $K^\times=GL_1(K)$. This bijection turns out to have all the familiar nice properties and gives the local Langlands correspondence for $GL_1$.

In other words, the link between the Brauer group and the "Langlands type" formulation of class field theory is that the computation of the Brauer group is used to define the reciprocity map and to prove all its nice properties. The computation of the Brauer group by itself does not establish the main results of class field theory.

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Global class field theory typically refers to the existence of a particular isomorphism (along with various compatibilities) $G(K/k)^{ab}\simeq C_k/N_{K/k} C_K$, where $K$ is a finite Galois extension. This can be recast, by dualizing, to say something about a correspondence between characters on $G(\bar k/k)$ and characters on $C_k$. These statements will be equivalent, but different proofs may not be...

I think you can prove it via Taylor-Wiles method (Kowalski mentions this in a survey paper referring to unpublished notes from a class Tunnell taught). But the proofs of global class field theory that I know are essentially cohomological (though they may avoid saying it). The statement about Brauer groups that you made is essentially what is necessary to prove that $(G(\bar k/k),C_{\bar k})$ is a class formation, from which a bit more work is necessary to prove class field theory (though you can deduce reciprocity laws from it).

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