Kan Complexes, proof of extension of a map to a product

Question

I'm reading a book about Kan Complexes in Simplicial Homotopy Theory (Curtis), and came across this theorem at the beginning : if $f : \Delta[n] \times \Lambda^k[m] \to K$ is a simplicial map and $K$ is a Kan complex, then $f$ has an extension from $\Delta[n] \times \Delta[m] \to K$.

The proof is fairly confusing to me : "$\Delta[n] \times \Lambda^k[m]$ can be obtained from $\Delta[n] \times \Delta[m]$ by successively adjoining a simplex and one of its faces, all other faces already lying in a subcomplex. Iterated application of the extension condition gives the lemma."

The extension condition is that if $f : \Lambda^k[m] \to K$ is a simplicial map and $K$ is a Kan complex, then $f$ has an extension from $\Delta[m] \to K$.

Could you help me with this ? I do not understand what he means by "successively adjoining a simplex", what "subcomplex" he's talking about and how he applies the extension condition. I'm a very beginner in the domain and any help would be very appreciated !

Answer 1

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The reason this works is that the inclusion map $i:\Delta[n]\times\Lambda^k[m]\hookrightarrow{}\Delta[n]\times\Delta[m]$ can be viewed as a composition. The maps in this composition are all monomorphisms of the form $i_{\ell}:X\hookrightarrow{}X\cup_{S}\Delta[m+n]$; that is, they adjoin one of the missing simplices, which all happen to be of dimension $m+n$. In particular, this is a pushout of a (generalized) horn inclusion, so it has the left lifting property with respect to Kan complexes. A detailed account of this decomposition can be found in, e.g., the appendix to Rezk's notes on quasicategories, but it's a good exercise to work it out yourself.