173 research outputs found
Coupling of quantum angular momenta: an insight into analogic/discrete and local/global models of computation
In the past few years there has been a tumultuous activity aimed at
introducing novel conceptual schemes for quantum computing. The approach
proposed in (Marzuoli A and Rasetti M 2002, 2005a) relies on the (re)coupling
theory of SU(2) angular momenta and can be viewed as a generalization to
arbitrary values of the spin variables of the usual quantum-circuit model based
on `qubits' and Boolean gates. Computational states belong to
finite-dimensional Hilbert spaces labelled by both discrete and continuous
parameters, and unitary gates may depend on quantum numbers ranging over finite
sets of values as well as continuous (angular) variables. Such a framework is
an ideal playground to discuss discrete (digital) and analogic computational
processes, together with their relationships occuring when a consistent
semiclassical limit takes place on discrete quantum gates. When working with
purely discrete unitary gates, the simulator is naturally modelled as families
of quantum finite states--machines which in turn represent discrete versions of
topological quantum computation models. We argue that our model embodies a sort
of unifying paradigm for computing inspired by Nature and, even more
ambitiously, a universal setting in which suitably encoded quantum symbolic
manipulations of combinatorial, topological and algebraic problems might find
their `natural' computational reference model.Comment: 17 pages, 1 figure; Workshop `Natural processes and models of
computation' Bologna (Italy) June 16-18 2005; to appear in Natural Computin
Microscopic description of 2d topological phases, duality and 3d state sums
Doubled topological phases introduced by Kitaev, Levin and Wen supported on
two dimensional lattices are Hamiltonian versions of three dimensional
topological quantum field theories described by the Turaev-Viro state sum
models. We introduce the latter with an emphasis on obtaining them from
theories in the continuum. Equivalence of the previous models in the ground
state are shown in case of the honeycomb lattice and the gauge group being a
finite group by means of the well-known duality transformation between the
group algebra and the spin network basis of lattice gauge theory. An analysis
of the ribbon operators describing excitations in both types of models and the
three dimensional geometrical interpretation are given.Comment: 19 pages, typos corrected, style improved, a final paragraph adde
Quantum Tetrahedra
We discuss in details the role of Wigner 6j symbol as the basic building
block unifying such different fields as state sum models for quantum geometry,
topological quantum field theory, statistical lattice models and quantum
computing. The apparent twofold nature of the 6j symbol displayed in quantum
field theory and quantum computing -a quantum tetrahedron and a computational
gate- is shown to merge together in a unified quantum-computational SU(2)-state
sum framework
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