Reshetikhin–Turaev invariant

In the mathematical field of quantum topology, the Reshetikhin–Turaev invariants (RT-invariants) are a family of quantum invariants of framed links. Such invariants of framed links also give rise to invariants of 3-manifolds via the Dehn surgery construction. These invariants were discovered by Nicolai Reshetikhin and Vladimir Turaev in 1991,[1] and were meant to be a mathematical realization of Witten's proposed invariants of links and 3-manifolds using quantum field theory.[2]

Overview

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To obtain an RT-invariant, one must first have a  -linear ribbon category at hand. Each  -linear ribbon category comes equipped with a diagrammatic calculus in which morphisms are represented by certain decorated framed tangle diagrams, where the initial and terminal objects are represented by the boundary components of the tangle. In this calculus, a (decorated framed) link diagram  , being a (decorated framed) tangle without boundary, represents an endomorphism of the monoidal identity (the empty set in this calculus), or in other words, an element of  . This element of   is the RT-invariant associated to  . Given any closed oriented 3-manifold  , there exists a framed link   in the 3-sphere   so that   is homeomorphic to the manifold   obtained by surgering   along  . Two such manifolds   and   are homeomorphic if and only if   and   are related by a sequence of Kirby moves. Reshetikhin and Turaev [1] used this idea to construct invariants of 3-manifolds by combining certain RT-invariants into an expression which is invariant under Kirby moves. Such invariants of 3-manifolds are known as Witten–Reshetikhin–Turaev invariants (WRT-invariants).

Examples

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Let   be a ribbon Hopf algebra over a field   (one can take, for example, any quantum group over  ). Consider the category  , of finite dimensional representations of  . There is a diagrammatic calculus in which morphisms in   are represented by framed tangle diagrams with each connected component decorated by a finite dimensional representation of  .[3] That is,   is a  -linear ribbon category. In this way, each ribbon Hopf algebra   gives rise to an invariant of framed links colored by representations of   (an RT-invariant).

For the quantum group   over the field  , the corresponding RT-invariant for links and 3-manifolds gives rise to the following family of link invariants, appearing in skein theory. Let   be a framed link in   with   components. For each  , let   denote the RT-invariant obtained by decorating each component of   by the unique  -dimensional representation of  . Then

 

where the  -tuple,   denotes the Kauffman polynomial of the link  , where each of the   components is cabled by the Jones–Wenzl idempotent  , a special element of the Temperley–Lieb algebra.

To define the corresponding WRT-invariant for 3-manifolds, first of all we choose   to be either a  -th root of unity or an  -th root of unity with odd  . Assume that   is obtained by doing Dehn surgery on a framed link  . Then the RT-invariant for the 3-manifold   is defined to be

 

where   is the Kirby coloring,   are the unknot with   framing, and   are the numbers of positive and negative eigenvalues for the linking matrix of   respectively. Roughly speaking, the first and second bracket ensure that   is invariant under blowing up/down (first Kirby move) and the third bracket ensures that   is invariant under handle sliding (second Kirby move).

Properties

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The Witten–Reshetikhin–Turaev invariants for 3-manifolds satisfy the following properties:

  1.   where   denotes the connected sum of   and  
  2.   where   is the manifold   with opposite orientation, and   denotes the complex conjugate of  
  3.  

These three properties coincide with the properties satisfied by the 3-manifold invariants defined by Witten using Chern–Simons theory (under certain normalization)[2]

Open problems

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Witten's asymptotic expansion conjecture

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Pick  . Witten's asymptotic expansion conjecture suggests that for every 3-manifold  , the large  -th asymptotics of   is governed by the contributions of flat connections.[4]

Conjecture: There exists constants   and   (depending on  ) for   and   for   such that the asymptotic expansion of   in the limit   is given by

 

where   are the finitely many different values of the Chern–Simons functional on the space of flat  -connections on  .

Volume conjecture for the Reshetikhin–Turaev invariant

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The Witten's asymptotic expansion conjecture suggests that at  , the RT-invariants grow polynomially in  . On the contrary, at   with odd  , in 2018 Q. Chen and T. Yang suggested the volume conjecture for the RT-invariants, which essentially says that the RT-invariants for hyperbolic 3-manifolds grow exponentially in   and the growth rate gives the hyperbolic volume and Chern–Simons invariants for the 3-manifold.[5]

Conjecture: Let   be a closed oriented hyperbolic 3-manifold. Then for a suitable choice of arguments,

 

where   is odd positive integer.

References

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  1. ^ a b Reshetikhin, Nicolai; Turaev, Vladimir G. (1991). "Invariants of 3-manifolds via link polynomials and quantum groups". Inventiones Mathematicae. 103 (1): 547–597. Bibcode:1991InMat.103..547R. doi:10.1007/BF01239527. S2CID 123376541.
  2. ^ a b Witten, Edward (1989). "Quantum field theory and the Jones polynomial". Communications in Mathematical Physics. 121 (3): 351–399. Bibcode:1989CMaPh.121..351W. doi:10.1007/BF01217730. S2CID 14951363.
  3. ^ Turaev, Vladimir G. (2016). Quantum invariants of knots and 3-manifolds. De Gruyter Studies in Mathematics. Vol. 18. Berlin: Walter de Gruyter. ISBN 978-3-11-044266-3.
  4. ^ Andersen, Jørgen Ellegaard; Hansen, Søren Kold (2006). "Asymptotics of the quantum invariants for surgeries on the figure 8 knot". Journal of Knot Theory and Its Ramifications. 15 (4): 479–548. arXiv:math/0506456. doi:10.1142/S0218216506004555. S2CID 8713259.
  5. ^ Chen, Qingtao; Yang, Tian (2018). "Volume conjectures for the Reshetikhin–Turaev and the Turaev–Viro invariants". Quantum Topology. 9 (3): 419–460. arXiv:1503.02547. doi:10.4171/QT/111. S2CID 18870964.
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