The n-Category Café

Mathieu,

this is most interesting. I am grateful that you took the time to share this information. This looks like it is the answer to something I have been struggling with for a while now.

I’m printing the references you provided, will have a look at them on the plane tomorrow (unless I fall asleep, as usual ;-).

For higher dimensions, Beppe Metere has studied the “ziggurat of exact sequences of $n$-groupoids”, but there is still no available reference as far as I know.

Googling, I found at least

Beppe Metere, (The Ziggurath of) exact sequences of $n$-groupoids (handwritten notes)

which already looks very helpful.

Thanks again! I might get back to you with further questions/comments here once I have had a chance to look into this.

The following may or may not be implicit in what Mathieu Dupoint said above, or in the literature which he provided, I haven’t fully absorbed that yet.

But today I realized that the construction of weak cokernels that I am talking about, is apparently nicely related to relative homotopy groups, in a very vivid way.

So recall the construction I am talking about:

given two 2-groupoids $C$ and $D$, and a 2-functor $$t : C \to D$$ which is “sufficiently injective” (let’s assume for simplicity that its component map is an injective maps on objects, morphisms and $2$-morphisms), then the weak cokernel of $t$ is the 2-groupoid

a) whose objects are 2-functors from the “fat point” $(\bullet \stackrel{\simeq}{\to} \circ)$ into $D$

b) whose morphisms are transformations of such 2-morphisms restricted to be trivial on $\bullet$ and to lie in the image of $t$ on $\circ$

c) 2-morphisms are modifications of such transformations, whose components lie in the image of $t$.

So a 2-morphism in $\mathrm{wcoker}(t)$ looks like a diagram of the form

in $D$, with $L$ in $C$.

Notice that this looks a bit like a 2-disk in $D$ whose boundary (2-1)-sphere is in the image of $t$.

But this is the way relative homotopy groups are defined.

Let $X$ be a topological space and $$t : A \hookrightarrow X$$ a subspace, then the elements of the $n$-homotopy group of $X$ relative to $A$ are those maps into $X$ which look like maps of the $n$-sphere into $X$ once we think of $A$ as being a single point.

More precisely, $$\pi_n(X,A) = \left\lbrace f : D^n \to X | \partial D^n \subset t(A) \right\rbrace$$ (I am suppressing the basepoints and the respect for them).

Clearly, this formula expresses the same kind of condition that enters the construction of the diagram displaeyed above.

In fact, I think that if I assume my 2-groupoids $C$ and $D$ to be the fundamental 2-groupoids $\Pi_2$ of $A$ and $X$, respectively, then then the weak cokernel of $$\Pi_2(A) \stackrel{\Pi_2(t)}{\to} \Pi_2(X)$$ is pretty much the 2-groupoid version of the $t$-relative homotopy 2-group.

If you see what I mean.

And indeed, the relative homotopy groups fit into a long exact sequence $$\pi_n(A) \stackrel{t}{\to} \pi_n(X) \to \pi_n(X,A) \to \pi_{n-1}(A) \to \cdots$$

which seem to correspond to precisely the corresponding long sequences of $n$-groupoids that we were talking about above.

(Sorry for the vagueness of these statements, I am just trying to quickly communicate a rough observation here.)

Thanks for constructing at least half the bridge between cats and homtopy theory.

0≃Ω(ΩY)→ΩKerF→ΩX→ΩFΩY→KerF→X→FY,
where each arrow is equivalent to the weak kernel of the following one.

In homotopy theory, as I’m sure you know but let’s let the rest of the blog in on the story:

for any map of spaces f: X –> Y
we have the homtopy fibre H_f (apparently to be called weak kernel) and a long sequence

…–> Omega H_f –> Omega X —> Omega Y –> H_f –> X –> Y

where each space is homotopy equvalent to the corresponding homotopy fibre

on the other hand, we have the mapping cone C_f and the Barratt-Puppe sequence

X –> Y –> C_f –> Sigma X –> Sigma Y –>…

N.B. Here Sigma means topological suspension NOT BX

also any map can be decomposed via a
fibration…