Hybrid Quantum-Classical Eigensolver Without Variation or Parametric
Gates
- URL: http://arxiv.org/abs/2008.11347v2
- Date: Mon, 16 Nov 2020 21:54:04 GMT
- Title: Hybrid Quantum-Classical Eigensolver Without Variation or Parametric
Gates
- Authors: Pejman Jouzdani, Stefan Bringuier
- Abstract summary: We present a process for obtaining the eigenenergy spectrum of electronic quantum systems.
This is achieved by projecting the Hamiltonian of a quantum system onto a limited effective Hilbert space.
A process for preparing short depth quantum circuits to measure the corresponding diagonal and off-diagonal terms of the effective Hamiltonian is given.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The use of near-term quantum devices that lack quantum error correction, for
addressing quantum chemistry and physics problems, requires hybrid
quantum-classical algorithms and techniques. Here we present a process for
obtaining the eigenenergy spectrum of electronic quantum systems. This is
achieved by projecting the Hamiltonian of a quantum system onto a limited
effective Hilbert space specified by a set of computational bases. From this
projection an effective Hamiltonian is obtained. Furthermore, a process for
preparing short depth quantum circuits to measure the corresponding diagonal
and off-diagonal terms of the effective Hamiltonian is given, whereby quantum
entanglement and ancilla qubits are used. The effective Hamiltonian is then
diagonalized on a classical computer using numerical algorithms to obtain the
eigenvalues. The use case of this approach is demonstrated for ground sate and
excited states of BeH$_2$ and LiH molecules, and the density of states, which
agrees well with exact solutions. Additionally, hardware demonstration is
presented using IBM quantum devices for H$_2$ molecule.
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