Quantum chemistry and charge transport in biomolecules with superconducting circuits
Scientific reports, 2016•nature.com
We propose an efficient protocol for digital quantum simulation of quantum chemistry
problems and enhanced digital-analog quantum simulation of transport phenomena in
biomolecules with superconducting circuits. Along these lines, we optimally digitize
fermionic models of molecular structure with single-qubit and two-qubit gates, by means of
Trotter-Suzuki decomposition and Jordan-Wigner transformation. Furthermore, we address
the modelling of system-environment interactions of biomolecules involving bosonic …
problems and enhanced digital-analog quantum simulation of transport phenomena in
biomolecules with superconducting circuits. Along these lines, we optimally digitize
fermionic models of molecular structure with single-qubit and two-qubit gates, by means of
Trotter-Suzuki decomposition and Jordan-Wigner transformation. Furthermore, we address
the modelling of system-environment interactions of biomolecules involving bosonic …
Abstract
We propose an efficient protocol for digital quantum simulation of quantum chemistry problems and enhanced digital-analog quantum simulation of transport phenomena in biomolecules with superconducting circuits. Along these lines, we optimally digitize fermionic models of molecular structure with single-qubit and two-qubit gates, by means of Trotter-Suzuki decomposition and Jordan-Wigner transformation. Furthermore, we address the modelling of system-environment interactions of biomolecules involving bosonic degrees of freedom with a digital-analog approach. Finally, we consider gate-truncated quantum algorithms to allow the study of environmental effects.
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