Litcius/Paper detail

Adaptive Variational Quantum Imaginary Time Evolution Approach for Ground State Preparation

Niladri Gomes, Anirban Mukherjee, Feng Zhang, Thomas Iadecola, Cai‐Zhuang Wang, Kai‐Ming Ho, Peter P. Orth, Yong‐Xin Yao

2021Advanced Quantum Technologies84 citationsDOIOpen Access PDF

Abstract

Abstract An adaptive variational quantum imaginary time evolution (AVQITE) approach is introduced that yields efficient representations of ground states for interacting Hamiltonians on near‐term quantum computers. It is based on McLachlan's variational principle applied to imaginary time evolution of variational wave functions. The variational parameters evolve deterministically according to equations of motions that minimize the difference to the exact imaginary time evolution, which is quantified by the McLachlan distance. Rather than working with a fixed variational ansatz, where the McLachlan distance is constrained by the quality of the ansatz, the AVQITE method iteratively expands the ansatz along the dynamical path to keep the McLachlan distance below a chosen threshold. This ensures the state is able to follow the quantum imaginary time evolution path in the system Hilbert space rather than in a restricted variational manifold set by a predefined fixed ansatz. AVQITE is used to prepare ground states of H 4 , H 2 O, and BeH 2 molecules, where it yields compact variational ansätze and ground state energies within chemical accuracy. Polynomial scaling of circuit depth with system size is shown through a set of AVQITE calculations of quantum spin models. Finally, quantum Lanczos calculations are demonstrated alongside AVQITE without additional quantum resource costs.

Topics & Concepts

Imaginary timeAnsatzGround stateQuantumMathematicsPhysicsQuantum systemQuantum algorithmHilbert spaceQuantum mechanicsVariational methodAdiabatic quantum computationScalingQuantum computerQuantum dynamicsWave functionQuantum stateQuantum operationPath (computing)QubitVariational principleLanczos resamplingPath integral formulationSpin (aerodynamics)Schrödinger equationSchrödinger's catTime evolutionBethe ansatzOpen quantum systemQuantum Computing Algorithms and ArchitectureQuantum many-body systemsAdvanced Physical and Chemical Molecular Interactions
Adaptive Variational Quantum Imaginary Time Evolution Approach for Ground State Preparation | Litcius