Symplectic Algebra for Quantum Computing Lattice Field Theory
ORAL
Abstract
Lattice Field Theory quatum computing starts with a Hamiltonian discretized on
the base lattice manifold but also, due to current Quantum Hardware design, require
that the field manifolds must be drastically reduced to very few Qubits per site. The Quantum Link or D-theory framework
(Brower, Chandrasekharan and Wiese) is presented as a natural structure to accomplish while preserving the Simplicial Algbra of the Hamiltonian
operator with very few Fermionic Quibts per site. This Fermionic structure can be converted into hard bosonic
(sigma) operators leading to a large class of Qubit Hamiltonians potentially
in the right Unversality class. This D-theory procedure is presented with particular
focus on the simplest compact U(1) field manifold and examples of 1 + 1 prototype Hamiltonians best suited
to earlly tests on NISQ era hardware are recommended.
the base lattice manifold but also, due to current Quantum Hardware design, require
that the field manifolds must be drastically reduced to very few Qubits per site. The Quantum Link or D-theory framework
(Brower, Chandrasekharan and Wiese) is presented as a natural structure to accomplish while preserving the Simplicial Algbra of the Hamiltonian
operator with very few Fermionic Quibts per site. This Fermionic structure can be converted into hard bosonic
(sigma) operators leading to a large class of Qubit Hamiltonians potentially
in the right Unversality class. This D-theory procedure is presented with particular
focus on the simplest compact U(1) field manifold and examples of 1 + 1 prototype Hamiltonians best suited
to earlly tests on NISQ era hardware are recommended.
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Publication: No completed manuscripts but may be before presentation.
Presenters
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Richard C Brower
Boston University
Authors
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Richard C Brower
Boston University