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    • CommentRowNumber1.
    • CommentAuthorUrs
    • CommentTimeOct 12th 2019
    • (edited Oct 12th 2019)

    I am stuck with understanding the rational cohomology of the group-completed configuration space of points in Euclidean 3-space

    ΩB Conf( 3) \Omega B_{{}_{\sqcup}} Conf\big( \mathbb{R}^3 \big)

    where Conf( 3)Conf\big( \mathbb{R}^3 \big) is a topological monoid under disjoint union of configurations of points (after translating them a little; as on p. 1-2 of Segal 73).

    I know the rational cohomology abstractly, but I am stuck interpreting the generators:

    Namely, by Theorem 1 in Segal 73 and by Example 2.5 in Møller-Raussen 85 we have a rational equivalence

    ΩB Conf( 3)Segal73Ω 3S 3 MollerRaussen85n0S 3 \Omega B_{{}_{\sqcup}} Conf\big( \mathbb{R}^3 \big) \underoverset{\simeq}{Segal 73}{\longrightarrow} \Omega^3 S^3 \underoverset{\simeq_{\mathbb{Q}}}{Moller-Raussen 85}{\longrightarrow} \underset{ n \neq 0 \in \mathbb{N} }{\sqcup} S^3

    So the rational cohomology of each connected component of ΩB Conf( 3)\Omega B_{{}_{\sqcup}} Conf\big( \mathbb{R}^3 \big) is free on a degree 3 generator, except in the connected component of the base point, where it is trivial.

    I am stuck understanding what these degree-3 generators are in terms of configurations of (virtual) points.

    One idea was to use the group completion theorem to express

    H (ΩB Conf( 3),)??H (Conf( 3),)[(π 0) 1] H_\bullet \big( \Omega B_{{}_{\sqcup}} Conf\big( \mathbb{R}^3 \big), \mathbb{Q} \big) \overset{??}{\simeq} H_\bullet \big( Conf \big( \mathbb{R}^3 \big), \mathbb{Q} \big) \big[ (\pi_0)^{-1} \big]

    I am unsure if the assumption of the group completion theorem is met (that π 0\pi_0 is in the center of the Pontrjagin ring). It seems intuitively obvious, but there might be a pitfall. The author of the first lines of arXiv:math/0511645 thinks that it applies.

    But assuming the group completion theorem applies, I next run into a contradiction, since

    H (Conf n( 3),)= H_\bullet \big( Conf_n\big( \mathbb{R}^3 \big), \mathbb{Q} \big) \;=\; \mathbb{Q}

    is just trivial. (One quick argument is that it’s the Sym(n)Sym(n)-invariants in this space, which are trivial. It’s also a special case of Theorem 4 in arXiv:math/0311323.)

    So I guess this means that the assumptions of the McDuff-Segal group completion theorem are not actually met here for the \sqcup-monoid of configurations in 3\mathbb{R}^3. (??)

    Or else I am making some silly mistake elsewhere.

    • CommentRowNumber2.
    • CommentAuthorUrs
    • CommentTimeOct 12th 2019
    • (edited Oct 12th 2019)

    Now I see that Theorem 6.3 in

    “Configuration spaces with summable labels” arXiv:math/9907073

    (with the remark above 4.20) gives an explicit description of the group completion of the configuration space in terms of the iterated loop space of another configuration space.

    That should help. Let’s see…

    • CommentRowNumber3.
    • CommentAuthorUrs
    • CommentTimeOct 12th 2019
    • (edited Oct 12th 2019)

    Ah, no that theorem 3.6 does not help here: By Boedigheimer 87, Example 11 it just reduces to a tautology in the present case.

    Hm…

    • CommentRowNumber4.
    • CommentAuthorUrs
    • CommentTimeOct 12th 2019
    • (edited Oct 12th 2019)

    Maybe another strategy:

    Is there any chance that the free loop space construction commutes with the delooping B B_{\sqcup} with respect to taking disjoint union of configurations?

    I.e. could there be a weak homotopy equivalence

    Maps(S 1,B Conf( 3))??B Maps(S 1,Conf( 3)) Maps(S^1, B_{\sqcup} Conf(\mathbb{R}^3)) \overset{?? }{\simeq} B_{\sqcup} Maps( S^1, Conf(\mathbb{R}^3))

    ??

    From geometric intuition this seems plausible, but otherwise I have no idea why this could work.

    • CommentRowNumber5.
    • CommentAuthorDavid_Corfield
    • CommentTimeOct 13th 2019

    This MO question of any interest?

    • CommentRowNumber6.
    • CommentAuthorUrs
    • CommentTimeOct 13th 2019

    As the single reply there says, the readily known results don’t help here.

    But it looks like today with Vincent we found the full statement and proof.

    • CommentRowNumber7.
    • CommentAuthorDavid_Corfield
    • CommentTimeOct 13th 2019

    To appear in the next one of the series of outputs?

    • CommentRowNumber8.
    • CommentAuthorUrs
    • CommentTimeOct 13th 2019

    Need to find a snappy title. This one is maybe too long: “Equivariant Cohomotopy cocycle spaces generate non-abelian quantum gauge field theory on Horava-Witten boundaries”.

    • CommentRowNumber9.
    • CommentAuthorUrs
    • CommentTimeOct 17th 2019
    • (edited Oct 17th 2019)

    I was wrong in #6: That fact you pointed to in #5 (here) is what I need:

    The scanning map

    Conf n( k)Ω kS k |deg=n Conf_n\big( \mathbb{R}^k \big) \longrightarrow \Omega^k S^k {}_{\vert deg = n}

    induces an isomorphism in cohomoloigy in degrees n/2\leq n/2.

    (I was previously conflating nn with kk, since I have this urge to confuse myself by sticking to a different convention than everyone else uses…)

    Where is this actually proven?

    On the first page of Segal 73 this is attributed to Barratt-Priddy 72 and Quillen 94.

    But I haven’t yet spotted it in either (of the second I only have a GoogleBooks-copy, which only shows the first few pages)

    • CommentRowNumber10.
    • CommentAuthorUrs
    • CommentTimeOct 18th 2019
    • (edited Oct 18th 2019)

    [edit: I see now the apparent contradiction in #1 came from me not properly feeding the Moller-Raussen formula through the homotopy fiber computing the based mapping space…]

    • CommentRowNumber11.
    • CommentAuthorUrs
    • CommentTimeOct 19th 2019
    • (edited Oct 19th 2019)

    So I finally understood my silly mistake that led to the above confusion.

    The correct rational model of Ω 3S 3\Omega^3 S^3 is instead n* \simeq_{\mathbb{Q}} \underset{n \in \mathbb{N}} {\sqcup} \ast (here)

    and so that matches the rational cohomology of the unordered configuration space Conf( 3)Conf(\mathbb{R}^3) being trivial in positive degree.

    My only remaining confusion is that I keep seeing a non-trivial rational 2-cocycle on the loop space ΩConf n( 3)\Omega Conf_n(\mathbb{R}^3) of the unordered configuration space for n3n \geq 3 points:

    Namely the Sym-invariant part of the respective graph complex is a dg-model for Conf n( 3)Conf_n(\mathbb{R}^3) itself, and so its based loop space is modeled by shifting all graphs down in degree by 1, and keeping only the co-unary part of the differential.

    But the 3-point interaction vertex has co-binary differential, exhibiting the “3-term relation”. Hence after passing to based loops, this becomes a closed 2-cocycle.

    Moreover, it seems immediate that this 2-cocycle is not exact: The only possible form of a trivialization is the graph obtained from it by inserting a single internal edge in the essentially unique way, and a quick explicit check shows that the differential of that is not the 3-point interaction vertex (but is zero).

    But if this is the case, we found a non-trivial 2 class on ΩConf 3( 3)\Omega Conf_3(\mathbb{R}^3); and then by adding in more disconnected free vertices also on all ΩConf n3( 3)\Omega Conf_{n \geq 3}(\mathbb{R}^3).

    At the same time, all these are loop spaces of rationally contractible spaces by the above.

    That’s a contradiction.

    I see two possibilities: Either I am making a really basic mistake in unwinding the definition of the graph differential. Or I am unwittingly violating some simply-connectedness assumption that invalidates the model for the looped configuration space by degree-shifted graphs.

    Hm…