34 research outputs found
ArQTiC: A full-stack software package for simulating materials on quantum computers
ArQTiC is an open-source, full-stack software package built for the
simulations of materials on quantum computers. It currently can simulate
materials that can be modeled by any Hamiltonian derived from a generic,
one-dimensional, time-dependent Heisenberg Hamiltonain. ArQTiC includes modules
for generating quantum programs for real- and imaginary-time evolution, quantum
circuit optimization, connection to various quantum backends via the cloud, and
post-processing of quantum results. By enabling users to seamlessly perform and
analyze materials simulations on quantum computers by simply providing a
minimal input text file, ArQTiC opens this field to a broader community of
scientists from a wider range of scientific domains.Comment: 8 pages, 7 figure
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ArQTiC: A full-stack software package for simulating materials on quantum computers
ArQTiC is an open-source, full-stack software package built for the
simulations of materials on quantum computers. It currently can simulate
materials that can be modeled by any Hamiltonian derived from a generic,
one-dimensional, time-dependent Heisenberg Hamiltonain. ArQTiC includes modules
for generating quantum programs for real- and imaginary-time evolution, quantum
circuit optimization, connection to various quantum backends via the cloud, and
post-processing of quantum results. By enabling users to seamlessly perform and
analyze materials simulations on quantum computers by simply providing a
minimal input text file, ArQTiC opens this field to a broader community of
scientists from a wider range of scientific domains
Recommended from our members
ArQTiC: A Full-stack Software Package for Simulating Materials on Quantum Computers
ArQTiC is an open-source, full-stack software package built for the simulations of materials on quantum computers. It currently can simulate materials that can be modeled by any Hamiltonian derived from a generic, one-dimensional, time-dependent Heisenberg Hamiltonian. ArQTiC includes modules for generating quantum programs for real- and imaginary-time evolution, quantum circuit optimization, connection to various quantum backends via the cloud, and post-processing of quantum results. By enabling users to seamlessly design, execute, and analyze materials simulations on quantum computers, ArQTiC opens this field to a broader community of scientists from a wider range of scientific domains
Exploring finite temperature properties of materials with quantum computers
Abstract Thermal properties of nanomaterials are crucial to not only improving our fundamental understanding of condensed matter systems, but also to developing novel materials for applications spanning research and industry. Since quantum effects arise at the nano-scale, these systems are difficult to simulate on classical computers. Quantum computers can efficiently simulate quantum many-body systems, yet current quantum algorithms for calculating thermal properties of these systems incur significant computational costs in that they either prepare the full thermal state on the quantum computer, or they must sample a number of pure states from a distribution that grows with system size. Canonical thermal pure quantum (TPQ) states provide a promising path to estimating thermal properties of quantum materials as they neither require preparation of the full thermal state nor require a growing number of samples with system size. Here, we present an algorithm for preparing canonical TPQ states on quantum computers. We compare three different circuit implementations for the algorithm and demonstrate their capabilities in estimating thermal properties of quantum materials. Due to its increasing accuracy with system size and flexibility in implementation, we anticipate that this method will enable finite temperature explorations of relevant quantum materials on near-term quantum computers