Abstract
We show how to perform universal Hamiltonian and adiabatic computing using a time-independent Hamiltonian on a 2D grid describing a system of hopping particles which string together and interact to perform the computation. In this construction, the movement of one particle is controlled by the presence or absence of other particles, an effective quantum field effect transistor that allows the construction of controlled-NOT and controlled-rotation gates. The construction translates into a model for universal quantum computation with time-independent two-qubit ZZ and XX+YY interactions on an (almost) planar grid. The effective Hamiltonian is arrived at by a single use of first-order perturbation theory avoiding the use of perturbation gadgets. The dynamics and spectral properties of the effective Hamiltonian can be fully determined as it corresponds to a particular realization of a mapping between a quantum circuit and a Hamiltonian called the space–time circuit-to-Hamiltonian construction. Because of the simple interactions required, and because no higher-order perturbation gadgets are employed, our construction is potentially realizable using superconducting or other solid-state qubits.
Highlights
The first proposals for quantum computers used time-dependent Hamiltonians to enact unitary quantum logic gates [1,2,3,4,5] and the first prototype quantum computers were realized using such time-dependent methods via electromagnetic resonance [6, 7]
Even though we reduce particular four-qubit interactions to two-qubit interactions by means of a single use of 1st order perturbation theory, it is unlikely that this trick is possible for arbitrary fourqubit interactions
The goal of this paper is to show how Hamiltonian quantum computation can be implemented using pairwise interactions between qubits, the construction given using pairwise interactions between spin-1/2 particles represents a viable path to implementable Hamiltonian quantum computation, using, e.g., spin-dependent electron tunneling [32]
Summary
We show how to perform universal Hamiltonian and adiabatic computing using a time-independent. Any further distribution of Hamiltonian on a 2D grid describing a system of hopping particles which string together and interact this work must maintain attribution to the to perform the computation. In this construction, the movement of one particle is controlled by the author(s) and the title of presence or absence of other particles, an effective quantum field effect transistor that allows the the work, journal citation and DOI. The construction translates into a model for universal quantum computation with time-independent two-qubit ZZ and XX+YY interactions on an (almost) planar grid.
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