The inverse limit functor

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last update: 31 January 2012

The functor $\lim_{\leftarrow}$

Let

A

be a ring. Let

I

be a partially ordered set.

An inverse system, or projective system, indexed by $I$ is a collection ${(E_{α}, f_{α β})}_{\underset{α \leq β}{α, β \in I}}$ such that

$E_{α}$ are $A -$ modules
$f_{α β} : E_{β} \to E_{α}$ are morphisms of $A -$ modules

such that

If $α, β, γ \in I$ and $α \leq β \leq γ$ then $f_{α γ} = f_{α β} \circ f_{β γ}$
If $α \in I$ then $f_{α α} = {id}_{E_{α}} .$

Let $(E_{α}, f_{α β})$ and $(F_{α}, g_{α β})$ be inverse systems indexed by $I$ . A morphism from $(E_{α})$ to $(F_{α})$ is a collection ${(u_{α})}_{α \in I}$ of $A -$ module morphisms $u_{α} : E_{α} \to F_{α}$ such that $if α, β \in I and α \leq β then u_{α} \circ f_{α β} = g_{α β} \circ u_{β}$

Let $(E_{α}, f_{α β})$ be a projective system indexed by $I$ . The inverse limit, or projective limit, of $E_{α}$ is the $A -$ module of coherent $I -$ sequences in $\prod_{α} E_{α},$ $\lim_{\leftarrow} E_{α} = {x = (x_{α}) \in \prod_{α} E_{α}| \begin{array}{l} If α, β \in I and α \leq β then \\ {pr}_{α} x = f_{α β} {pr}_{β} x \end{array}}$ with the morphisms $\begin{array}{rrcl} f_{α} : & \lim_{\leftarrow} E_{α} & \to & E_{α} \\ x = (x_{α}) & \mapsto & x_{α} . \end{array}$

Let $(E_{α}, f_{α β})$ and $(F_{α}, g_{α β})$ be projective systems indexed by $I$ . Let $u_{α} : E_{α} \to F_{α}$ be a morphism of projective systems.

The inverse limit, or projective limit, of $u_{α}$ is $u = \lim_{\leftarrow} u_{α}$ given by $\begin{array}{rrcl} u : & \lim_{\leftarrow} E_{α} & \to & \lim_{\leftarrow} F_{α} \\ (y_{α}) & \mapsto & (u_{α} (y_{α})) . \end{array}$

Homework questions

HW 1:

Let $u_{α} : E_{α} \to F_{α}$ be a morphism of inverse systems and let $u = \lim_{\leftarrow} u_{α} .$ Show that $u : \lim_{\leftarrow} E_{α} \to \lim_{\leftarrow} F_{α}$ is the unique morphism such that $if α \in I then g_{α} \circ u = u_{α} \circ f_{α}, where E = \lim_{\leftarrow} E_{α} and F = \lim_{\leftarrow} F_{α} .$

HW 2:

The universal property of $\lim_{\leftarrow} E_{α} .$

Let $(E_{α}, f_{α β})$ be an inverse system. Let $F$ be an $A -$ module with morphisms $v_{α} : F \to E_{α}$ such that $if α, β \in I and α \leq β then f_{α β} \circ v_{β} = v_{α} .$ Then there is a unique morphism $v : F \to \lim_{\leftarrow} E_{α}$ such that $if α \in I then v_{α} = f_{α} \circ v .$

HW 3:

$\lim_{\leftarrow}$ is a functor.

Show that $\lim_{\leftarrow} : {\begin{array}{c} inverse systems \\ of A -modules \end{array}} \to {\begin{array}{c} A -modules \end{array}}$ is a covariant functor: $\lim_{\leftarrow} (v_{α} \circ u_{α}) = (\lim_{\leftarrow} v_{α}) \circ (\lim_{\leftarrow} u_{α})$ for morphisms $(v_{α})$ and $(u_{α})$ of inverse systems.

HW 4:

Show that $\lim_{\leftarrow}$ is a left exact functor.

HW 5:

Give an example which shows that $\lim_{\leftarrow}$ is not an exact functor:

		Example solution.
	Let $I = ℤ_{> 0}$ , $E_{n} = ℤ$ and $\begin{array}{rrcl} f_{n m} : & ℤ & \to & ℤ \\ x & \mapsto & 3^{m - n} x \end{array} for n \leq m .$ Let $\begin{array}{rrcl} u_{n} : & E_{n} & \to & \frac{ℤ}{2 ℤ} . \end{array}$ Then $\lim_{\leftarrow} \frac{ℤ}{2 ℤ} = \frac{ℤ}{2 ℤ},$ $\lim_{\leftarrow} 0 = 0$ and $E_{n} \overset{u_{n}}{\to} \frac{ℤ}{2 ℤ} \to 0$ is exact, but $\lim_{\leftarrow} E_{n} \overset{u}{\to} \lim_{\leftarrow} \frac{ℤ}{2 ℤ} \to \lim_{\leftarrow} 0$ is not exact. $□$

HW 6:

A partially ordered set $I$ is left filtered if $I$ satisfies $\begin{array}{c} if α, β \in I then there exists λ \in I such that \\ λ \leq α and λ \leq β . \end{array}$ Assume $I$ is a left filtered partially ordered set. Let $F$ be an $A -$ module and let $(E_{α}, f_{α β})$ be the inverse system given by $E_{α} = F and f_{α β} = {id}_{F}$ for $α, β \in I$ with $α \leq β .$ Show that $\lim_{\leftarrow} E_{α} = {x = (x_{α}) \in \prod_{α} E_{α}| if α, β \in I then x_{α} = x_{β}} ,$ the diagonal in $\prod_{α} E_{α} .$

HW 7:

Let $I$ be a partially ordered set with equality as the partial order. Let $(E_{α}, f_{α β})$ be an inverse system on $I$ . Show that $\lim_{\leftarrow} E_{α} = \prod_{α} E_{α} .$

HW 8:

Let $I$ be a partially ordered set. Show that there exists an inverse system $(E_{α}, f_{α β})$ indexed by $I$ such that

if $α \in I$ then $E_{α} \neq \emptyset$ ,
if $α, β \in I$ and $α \leq β$ then $f_{α β} : E_{β} \to E_{α}$ is surjective,
$\lim_{\leftarrow} E_{α} = \emptyset .$

Notes and References

The basic theory of projective limits appears in [Bou, Ens, Ch III §7], [Bou, Alg Ch I §10], [Bou, Alg Ch II §6], [Bou, Top Gen Ch I §4.4], [Bou, Top Gen Ch II §2.7 and §3.5], [Bou, Top Gen Ch III §7] and [AM, Ch 10 p.103].

In particular the solution to HW1 is given in [Bou, Ens. Ch III §7 No.2 Cor 1] which shows that HW2 should really be done before HW1. The solution to HW2 is given in [Bou, Ens. Ch III §7 No.2 Prop 1], the solution to HW3 is given in [Bou, Ens. Ch III §7 No.2 Cor 2], the solution to HW4 is given in [Bou, Alg Ch II §6 Prop 1] and [AM, Prop 10.2], and the example in HW5 is taken from [Bou, Alg Ch II §6 Ex 1] (an alternative is in [AM, Ch 10 Ex 2]). HW6 is taken from [Bou, Ens. Ch III §7 No.1 Example 2], HW7 is taken from [Bou, Ens. Ch III §7 No.1 Example 1], and the solution to HW8 is found in [Bou, Ens. Ch III §7 Ex 4]. All of these, except perhaps HW8, are routine enough that the mathematician experienced at writing proofs should have no need to refer to the solutions.

References

References?

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