Litcius/Paper detail

Alternative approach to quantum imaginary time evolution

Pejman Jouzdani, Calvin W. Johnson, Eduardo R. Mucciolo, Ionel Stetcu

2022Physical review. A/Physical review, A29 citationsDOIOpen Access PDF

Abstract

There is increasing interest in quantum algorithms (QAs) that are based on the imaginary time evolution (ITE), a successful classical numerical approach to obtain ground states. However, most of the proposals so far require heavy postprocessing computational steps on a classical computer, such as solving linear equations. Here we provide an alternative approach to implement ITE. A key feature in our approach is the use of an orthogonal basis set: the propagated state is efficiently expressed in terms of orthogonal basis states at every step of the evolution. We argue that the number of basis states needed at those steps to achieve an accurate solution can be kept on the order of $n$, the number of qubits, by controlling the precision (number of significant digits) and the imaginary time increment. The number of quantum gates per imaginary time step is estimated to be polynomial in $n$. Additionally, while in many QAs the locality of the Hamiltonian is a key assumption, in our algorithm this restriction is not required. This characteristic of our algorithm renders it useful for studying highly nonlocal systems, such as the occupation-representation nuclear shell model. We illustrate our algorithm through numerical implementation on an IBM quantum simulator.

Topics & Concepts

Imaginary timeHamiltonian (control theory)QubitThe ImaginaryBasis (linear algebra)Quantum computerLocalityQuantumQuantum algorithmTime complexityMathematicsAlgorithmComputer scienceApplied mathematicsMathematical optimizationQuantum mechanicsQuantum dynamicsPhysicsGeometryPsychotherapistLinguisticsSupersymmetric quantum mechanicsPhilosophyPsychologyQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum many-body systems