Related papers: Synthesis of Energy-Conserving Quantum Circuits with XY interaction

Synthesis of Energy-Conserving Quantum Circuits with XY interaction

URL: http://arxiv.org/abs/2309.11051v3
Date: Mon, 23 Sep 2024 01:20:42 GMT
Title: Synthesis of Energy-Conserving Quantum Circuits with XY interaction
Authors: Ge Bai, Iman Marvian,
Abstract summary: We study quantum circuits constructed from $sqrtiSWAP$ gates and entangling gates that can be realized with the XX+YY interaction alone. Such gates preserve the Hamming weight of states in the computational basis. We show how a general energy-conserving unitary can be synthesized using only a sequence of $sqrtiSWAP$ gates and 2 ancillary qubits.
Score: 0.2302001830524133
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: We study quantum circuits constructed from $\sqrt{iSWAP}$ gates and, more generally, from the entangling gates that can be realized with the XX+YY interaction alone. Such gates preserve the Hamming weight of states in the computational basis, which means they respect the global U(1) symmetry corresponding to rotations around the z axis. Equivalently, assuming that the intrinsic Hamiltonian of each qubit in the system is the Pauli Z operator, they conserve the total energy of the system. We develop efficient methods for synthesizing circuits realizing any desired energy-conserving unitary using XX+YY interaction with or without single-qubit rotations around the z-axis. Interestingly, implementing generic energy-conserving unitaries, such as CCZ and Fredkin gates, with 2-local energy-conserving gates requires the use of ancilla qubits. When single-qubit rotations around the z-axis are permitted, our scheme requires only a single ancilla qubit, whereas with the XX+YY interaction alone, it requires 2 ancilla qubits. In addition to exact realizations, we also consider approximate realizations and show how a general energy-conserving unitary can be synthesized using only a sequence of $\sqrt{iSWAP}$ gates and 2 ancillary qubits, with arbitrarily small error, which can be bounded via the Solovay-Kitaev theorem. Our methods are also applicable for synthesizing energy-conserving unitaries when, rather than the XX+YY interaction, one has access to any other energy-conserving 2-body interaction that is not diagonal in the computational basis, such as the Heisenberg exchange interaction. We briefly discuss the applications of these circuits in the context of quantum computing, quantum thermodynamics, and quantum clocks.

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