Difference between revisions of "WKO"

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{{note|BP}} B. Berceanu and S. Papadima, Universal Representations of Braid and Braid-Permutation Groups, {{arXiv|0708.0634}}.  
 
{{note|BP}} B. Berceanu and S. Papadima, Universal Representations of Braid and Braid-Permutation Groups, {{arXiv|0708.0634}}.  
  
{{note|BH}} T. Brendle and A. Hatcher, Configuration Spaces of Rings and Wickets, {{arXiv|0805.4354||.  
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{{note|BH}} T. Brendle and A. Hatcher, Configuration Spaces of Rings and Wickets, {{arXiv|0805.4354}}.  
  
 
{{note|EK}} P. Etingof and D. Kazhdan, Quantization of Lie Bialgebras, I, Selecta Mathematica, New Series 2 (1996) 1-41, {{arXiv|q-alg/9506005}}.  
 
{{note|EK}} P. Etingof and D. Kazhdan, Quantization of Lie Bialgebras, I, Selecta Mathematica, New Series 2 (1996) 1-41, {{arXiv|q-alg/9506005}}.  

Revision as of 17:22, 8 January 2012

Template:WClips/Companion

In Preparation

The information below is preliminary and cannot be trusted! (v)

Finite Type Invariants of W-Knotted Objects: From Alexander to Kashiwara and Vergne

Joint with Zsuzsanna Dancso
WKO.pdf: last updated January 8, 2012. first edition: Not yet.

Abstract. w-Knots, and more generally, w-knotted objects (w-braids, w-tangles, etc.) make a class of knotted objects which is wider but weaker than their "usual" counterparts. To get (say) w-knots from u-knots, one has to allow non-planar "virtual" knot diagrams, hence enlarging the the base set of knots. But then one imposes a new relation, the "overcrossings commute" relation, further beyond the ordinary collection of Reidemeister moves, making w-knotted objects a bit weaker once again.

The group of w-braids was studied (under the name "welded braids") by Fenn, Rimanyi and Rourke [FRR] and was shown to be isomorphic to the McCool group [Mc] of "basis-conjugating" automorphisms of a free group F_n - the smallest subgroup of \operatorname{Aut}(F_n) that contains both braids and permutations. Brendle and Hatcher [BH], in work that traces back to Goldsmith [Gol], have shown this group to be a group of movies of flying rings in {\mathbb R}^3. Satoh [Sa] studied several classes of w-knotted objects (under the name "weakly-virtual") and has shown them to be closely related to certain classes of knotted surfaces in {\mathbb R}^4. So w-knotted objects are algebraically and topologically interesting.

In this article we study finite type invariants of several classes of w-knotted objects. Following Berceanu and Papadima [BP], we construct a homomorphic universal finite type invariant of w-braids, and hence show that the McCool group of automorphisms is "1-formal". We also construct a homomorphic universal finite type invariant of w-tangles. We find that the universal finite type invariant of w-knots is more or less the Alexander polynomial (details inside).

Much as the spaces {\mathcal A} of chord diagrams for ordinary knotted objects are related to metrized Lie algebras, we find that the spaces {\mathcal A}^w of "arrow diagrams" for w-knotted objects are related to not-necessarily-metrized Lie algebras. Many questions concerning w-knotted objects turn out to be equivalent to questions about Lie algebras. Most notably we find that a homomorphic universal finite type invariant of w-knotted trivalent graphs is essentially the same as a solution of the Kashiwara-Vergne [KV] conjecture and much of the Alekseev-Torrosian [AT] work on Drinfel'd associators and Kashiwara-Vergne can be re-interpreted as a study of w-knotted trivalent graphs.

The true value of w-knots, though, is likely to emerge later, for we expect them to serve as a warmup example for what we expect will be even more interesting - the study of virtual knots, or v-knots. We expect v-knotted objects to provide the global context whose projectivization (or "associated graded structure") will be the Etingof-Kazhdan theory of deformation quantization of Lie bialgebras [EK].

The paper. WKO.pdf, WKO.zip.

Related Mathematica Notebooks. "The Kishino Braid" (Source, PDF), "Dimensions" (Source, PDF), "wA" (Source, PDF), "InfinitesimalAlexanderModules" (Source, PDF).

Related talks. Oberwolfach-0805, MSRI-0808, Northeastern-081028, Trieste-0905, Bonn-0908.

Links. SandersonsGarden.html.

Related Scratch Work is under Pensieve: WKO and Pensieve: Arrow_Diagrams_and_gl(N).

References.

[AT] ^  A. Alekseev and C. Torossian, The Kashiwara-Vergne conjecture and Drinfeld's associators, arXiv:0802.4300.

[BP] ^  B. Berceanu and S. Papadima, Universal Representations of Braid and Braid-Permutation Groups, arXiv:0708.0634.

[BH] ^  T. Brendle and A. Hatcher, Configuration Spaces of Rings and Wickets, arXiv:0805.4354.

[EK] ^  P. Etingof and D. Kazhdan, Quantization of Lie Bialgebras, I, Selecta Mathematica, New Series 2 (1996) 1-41, arXiv:q-alg/9506005.

[FRR] ^  R. Fenn, R. Rimanyi and C. Rourke, The Braid-Permutation Group, Topology 36 (1997) 123-135.

[Gol] ^  D. L. Goldsmith, The Theory of Motion Groups, Mich. Math. J. 28-1 (1981) 3-17.

[KV] ^  M. Kashiwara and M. Vergne, The Campbell-Hausdorff Formula and Invariant Hyperfunctions, Invent. Math. 47 (1978) 249-272.

[Mc] ^  J. McCool, On Basis-Conjugating Automorphisms of Free Groups, Can. J. Math. 38-6(1986) 1525-1529.

[Sa] ^  S. Satoh, Virtual Knot Presentations of Ribbon Torus Knots, J. of Knot Theory and its Ramifications 9-4 (2000) 531-542.