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The first one $\mathrm{Spec}\mathbb{C}[[t]]$ is a scheme, the second one $\mathrm{Spf}\mathbb{C}[[t]]$ is a formal scheme. In my mind they both realize an "infinite order infinitesimal neighbourhood of a point in $\mathbb{A}^1_{\mathbb{C}}$ ". The "formal disc" is an increasing limit of finite order infinitesimal neighbourhoods; pretty much like an increasing union of closed subschemes that are thickenings of the reduced point. How should I think of the others? So

What's the difference between these objects, intuitively? How are these objects related to the fact that $\mathbb{C}[[t]]$ actually carries an adic topology? What is each of them best suitable for? When to "use" one and when the other(s)?

Of course the same questions could be asked replacing $\mathbb{C}[[t]]$ with any complete local ring $A=\hat A$.

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    $\begingroup$ What is $\mathrm{Specan}\,\mathbf{C}[[t]]$? $\endgroup$ May 18, 2018 at 21:08
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    $\begingroup$ @PiotrAchinger : Wouldn't this be the analytic spectrum? $\endgroup$
    – Watson
    May 18, 2018 at 21:45
  • $\begingroup$ @Piotr Achinger: to be honest, I don't know exactly which ingredients of $\mathbb{C}[[t]]$ are needed to define the analytic spectrum: maybe $\mathbb{C}$ should be counted with its own norm topology? or the discrete topology? Let's say I'm open to hear what people that know adic stuff will say $\endgroup$
    – Qfwfq
    May 19, 2018 at 0:13
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    $\begingroup$ In adic spaces, I believe analytic can refer to points associated to valuations whose kernel is not open in the topology of the ring. But I don't know whether that is the referent in this case. I don't like the terminology though. It gives me incredible urgers to define $\mathrm{Swalnut}\mathbb{C}[[t]], \mathrm{Spumpkin}\mathbb{C}[[t]], \ldots$ $\endgroup$ Dec 19, 2018 at 18:36
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    $\begingroup$ Nothing against more readable notation such as $\mathrm{Spec}_{\mathrm{an}}$, $\mathrm{Spec}_{\mathrm{f}}$...? $\endgroup$
    – YCor
    Dec 20, 2018 at 12:46

3 Answers 3

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In a nutshell:

  • $\mathrm{Spec}~\mathbb{C}[[t]]$ Is a “trait” i.e. the spectrum of a discrete valuation domain, with a generic (open) point and a closed point. It might be imagined as a refinement of the usual algebraic germ of the affine line at the origin, namely $\mathrm{Spec}~\mathbb{C}[t]_{\langle t \rangle}$.
  • $\mathrm{Spf}~\mathbb{C}[[t]]$ is the completion of $\mathbb{A}^1_{\mathbb{C}}$ along the origin. It is interpreted as the union of all the infinitesimal neighborhoods of the origin in the line. As such, is strictly contained in any space of germs: there is a chain of canonical morphisms $$\mathrm{Spf}~\mathbb{C}[[t]] \to \mathrm{Spec}~\mathbb{C}[[t]] \to \mathrm{Spec}~\mathbb{C}[t]_{\langle t \rangle}$$
  • $\mathrm{Specan}~\mathbb{C}\{t\}$ where $\mathbb{C}\{t\}$ denotes the local ring of convergent power series at the origin represents the analytic germ of $\mathbb{C}$ at the origin, usually denoted $(\mathbb{C}, 0)$. It also sits between $\mathrm{Spf}~\mathbb{C}[[t]]$ and $\mathrm{Spec}~\mathbb{C}[t]_{\langle t \rangle}$.

The topology in the sheaf of rings of $\mathrm{Spf}~\mathbb{C}[[t]]$ is responsible for its hidden part. If instead of $\mathbb{C}$ one takes an ultrametric field, then the chimeric “generic fiber” would be a model for the rigid analytic closed disk. For $\mathbb{C}$ one does not have something like the complete valuation subring playing the role of $p$-adic integers for $\mathbb{Q}_p$.

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  • $\begingroup$ I agree you have a generic fiber on $\mathrm{Spf}~\mathbb{C}[[t]]$, as you say. The point is that $\mathbb{C}\{t\}$ makes sense in the realm of complex analytic geometry, that, As far as I understand, is not covered by adic methods. $\endgroup$
    – Leo Alonso
    Dec 21, 2018 at 13:32
  • $\begingroup$ Sorry, I read what you wrote to quickly. I just saw $\mathbb{C}\{t\}$ and believed it was the usual Tate algebra since it is a standard notation for it. I remove my previous comment that was off. $\endgroup$ Dec 21, 2018 at 13:53
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One good way of seeing the difference between $\mathrm{Spec}\,\mathbb{C}[[t]]$ and $\mathrm{Spf}\,\mathbb{C}[[t]]$ is to look at what functors they represent on affine schemes. In fact we have $$\mathrm{Hom}(\mathrm{Spec}\,A,\mathrm{Spec}\,\mathbb{C}[[t]])=\mathrm{Hom}(\mathbb{C}[[t]],A)$$ This is just the ordinary morphisms of rings, and it's not particularly different from any map from a DVR into $A$.

$$\mathrm{Hom}(\mathrm{Spec}\,A,\mathrm{Spf}\,\mathbb{C}[[t]])=\mathrm{colim}_n\mathrm{Hom}(\mathbb{C}[t]/(t^n),A)=\{a\in A\mid a\textrm{ nilpotent }\}$$ More generally, when instead of $\mathrm{Spec}\,A$ we put any scheme $X$, we get the global sections of $X$ that are locally nilpotent (i.e. nilpotent when restricted on affine schemes).

In this sense you can think of $\mathrm{Spf}\,\mathbb{C}[[t]]$ as the completion of $\mathrm{Spec}\,\mathbb{C}[t]$ at the origin: maps into $\mathrm{Spf}\,\mathbb{C}[[t]]$ are the same thing as maps into $\mathrm{Spec}\,\mathbb{C}[t]$ whose set-theoretic image is (contained in) the origin.

Note that this works for all affine formal schemes: if $R$ is a ring and $I$ an ideal, $\mathrm{Spf}\,R^\wedge_I$ represents the functor sending $X$ to the maps of schemes $X\to \mathrm{Spec}\,R$ such that the set-theoretic image is contained in $V(I)$.

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  • $\begingroup$ Interesting that you give an interpretation of maps into the thing (not from it) $\endgroup$
    – Qfwfq
    Dec 20, 2018 at 12:17
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    $\begingroup$ And this is why $\mathrm{Spf}\,\mathbb{C}[[t]]$ is the union of all the infinitesimal neighborhoods of the origin. $\endgroup$
    – Leo Alonso
    Dec 20, 2018 at 12:17
  • $\begingroup$ @Qfwfq This is fairly standard while working with schemes/formal schemes/whatever. Maps into things are usually easier to understand than maps out of things, that's why the Yoneda embedding works so well. I personally prefer to embed schemes and formal schemes into étale sheaves on $\mathrm{Aff}_R$ rather than locally ringed spaces for precisely this reason. $\endgroup$ Dec 20, 2018 at 12:29
  • $\begingroup$ @DenisNardin The maps give you this infinitesimal feeling, of course but the ringed space point of view expresses the "hidden part". For instance, non open primes on the structure sheaf correspond to generic points of the generic fiber, i.e. the associated rigid space. $\endgroup$
    – Leo Alonso
    Dec 20, 2018 at 12:35
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    $\begingroup$ @LeoAlonso I should really learn that theory some day... I should probably mention that when homotopy theorists talk about formal schemes, they almost invariably mean "ind-schemes" (which are related, but not quite the same thing as an algebraic geometer's formal schemes), which might explain my preference for Yoneda. $\endgroup$ Dec 21, 2018 at 15:18
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To complement the other answers, I would like to add a word on the analytic spectrum $\mathrm{Specan}(\mathbb{C}[[t]])$.

First, let me say that I am not sure what $\mathrm{Specan}$ means and have no idea where the notation comes from. On the other hand, it makes sense to consider the analytic spectrum of $\mathbb{C}[[t]]$ in R. Huber's theory of adic analytic spaces (where it would be called $\mathrm{Spa}(\mathbb{C}[[t]],\mathbb{C}[[t]])$) and in V. Berkovich's theory of analytic spaces (where it would be called $\mathcal{M}(\mathbb{C}[[t]])$ ; one would also need to prescribe the absolute of $t$, say $|t| = r \in (0,1)$, because the theory requires actual absolute values and not merely equivalence classes, i.e. valuations, but this is not really an issue).

Let me start with adic spaces. In this case, the spectrum is made of one closed point ($t=0$) and one open point (associated to the $t$-adic valuation). This open point is really the generic point of the space. More generally, you can associate (fully faithfully) an adic space to any sufficiently nice formal scheme and take its generic fiber inside the category of adic spaces. So here you really have the formal scheme again but, in the underlying space, you see its special fiber and its generic fiber (whereas $\mathrm{Spf}(\mathbb{C}[[t]])$ only shows the special fiber).

(Everything here looks quite similar to $\mathrm{Spec}(\mathbb{C}[[t]])$, so one may wonder why bother with formal schemes, fancy analytic spaces, etc. This is a only because the chosen situation is very simple (affine in particular) and you will have a hard time representing infinitesimal neighbourhoods by algebraic objects very quickly as soon as you start glueing.)

The situation with Berkovich spaces is very similar except that you will see a segment $[0,r]$ instead of two points. The point $0$ corresponds to $t=0$ and the other points all correspond to $t$-adic absolute values with different normalizations (given by $|t| = s$ for $s\in (0,r]$). Here again, you see a special fiber and a generic fiber (and even several equivalent copies of it). Note that the underlying space is Hausdorff and compact. This is a general feature of Berkovich spaces which is quite nice, although it is not clear how useful it would be in this particular situation.

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  • $\begingroup$ I've edited the title to accomodate both objects $\mathrm{Specan}\mathbb{C}[[t]]$ and $\mathrm{Specan}\mathbb{C}\{t\}$ (and maybe others) whatever definition of "analytic spectrum" one is willing to use. $\endgroup$
    – Qfwfq
    Dec 21, 2018 at 13:45

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