Kauffman, L. (2010). Topological Quantum Information, Khovanov Homology and the Jones Polynomial. Perimeter Institute for Theoretical Physics. https://pirsa.org/10050049

MLA

Kauffman, Louis. Topological Quantum Information, Khovanov Homology and the Jones Polynomial. Perimeter Institute for Theoretical Physics, May. 13, 2010, https://pirsa.org/10050049

BibTex

@misc{ scivideos_PIRSA:10050049,
doi = {10.48660/10050049},
url = {https://pirsa.org/10050049},
author = {Kauffman, Louis},
keywords = {Quantum Information, Quantum Gravity},
language = {en},
title = {Topological Quantum Information, Khovanov Homology and the Jones Polynomial},
publisher = {Perimeter Institute for Theoretical Physics},
year = {2010},
month = {may},
note = {PIRSA:10050049 see, \url{https://scivideos.org/pirsa/10050049}}
}

In this talk (based on arXiv:1001.0354) we give a quantum statistical interpretation for the Kauffmann bracket polynomial state sum <K> for the Jones polynomial. We use this quantum mechanical interpretation to give a new quantum algorithm for computing the Jones polynomial. This algorithm is useful for its conceptual simplicity, and it applies to all values of the polynomial variable that lie on the unit circle in the complex plane. Letting C(K) denote the Hilbert space for this model, there is a natural unitary transformation U from C(K) to itself such that <K> = <F|U|F> where |F> is a sum over basis states for C(K). The quantum algorithm arises directly from this formula via the Hadamard Test. We then show that the framework for our quantum model for the bracket polynomial is a natural setting for Khovanov homology. The Hilbert space C(K) of our model has basis in one-to-one correspondence with the enhanced states of the bracket state summmation and is isomorphic with the chain complex for Khovanov homology with coefficients in the complex numbers. We show that for the Khovanov boundary operator d defined on C(K) we have the relationship dU + Ud = 0.
Consequently, the unitary operator U acts on the Khovanov homology, and we therefore obtain a direct relationship between Khovanov homology and this quantum algorithm for the Jones polynomial. The formula for the Jones polynomial as a graded Euler characteristic is now expressed in terms of the eigenvalues of U and the Euler characteristics of the eigenspaces of U in the homology. The quantum algorithm given here is inefficient, and so it remains an open problem to determine better quantum algorithms that involve both the Jones polynomial and the Khovanov homology.