Quantum geometry and quantum algorithms

A Marzuoli; Adler R; Aharonov D Arad I; Aharonov D Jones V Landau Z; Ambjorn J; Ambjorn J; Arnowitt R; Atiyah M F; Bar-Natan D; Birman J S; Birman J S Brendle T E; Carlip S; Dehornoy P; Fomenko A T; Garnerone S Marzuoli A Rasetti A; Garnerone S Marzuoli A Rasetti M; Guadagnini E; Hopcroft J E; Jones V F R; Kauffman L H Lomonaco S J; Lickorish W B R; Lloyd S; M Rasetti; Menasco W; Misner C W; Ohtsuki T (ed); Quinn F; Regge T; S Garnerone; Thurston W P; Weinberg S; Wheeler J A; Wocjan P Yard J

research

Quantum geometry and quantum algorithms

Abstract

Motivated by algorithmic problems arising in quantum field theories whose dynamical variables are geometric in nature, we provide a quantum algorithm that efficiently approximates the colored Jones polynomial. The construction is based on the complete solution of Chern-Simons topological quantum field theory and its connection to Wess-Zumino-Witten conformal field theory. The colored Jones polynomial is expressed as the expectation value of the evolution of the q-deformed spin-network quantum automaton. A quantum circuit is constructed capable of simulating the automaton and hence of computing such expectation value. The latter is efficiently approximated using a standard sampling procedure in quantum computation.Comment: Submitted to J. Phys. A: Math-Gen, for the special issue ``The Quantum Universe'' in honor of G. C. Ghirard