A Shift Selection Strategy for Parallel Shift-invert Spectrum Slicing in Symmetric Self-consistent Eigenvalue Computation

Williams‐Young, David B.; Beckman, Paul G.; Yang, Chao

doi:10.1145/3409571

Cited by 5 publications

(2 citation statements)

References 37 publications

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“…In NWChemEx , we adopt the spectrum slicing technique − to design an eigensolver that is more scalable. The basic idea is to divide the desired part of the spectrum into several spectrum slices, each containing roughly the same number of eigenvalues.…”

Section: Solversmentioning

confidence: 99%

From NWChem to NWChemEx: Evolving with the Computational Chemistry Landscape

et al. 2021

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Since the advent of the first computers, chemists have been at the forefront of using computers to understand and solve complex chemical problems. As the hardware and software have evolved, so have the theoretical and computational chemistry methods and algorithms. Parallel computers clearly changed the common computing paradigm in the late 1970s and 80s, and the field has again seen a paradigm shift with the advent of graphical processing units. This review explores the challenges and some of the solutions in transforming software from the terascale to the petascale and now to the upcoming exascale computers. While discussing the field in general, NWChem and its redesign, NWChemEx, will be highlighted as one of the early co-design projects to take advantage of massively parallel computers and emerging software standards to enable large scientific challenges to be tackled.

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Section: Solversmentioning

confidence: 99%

From NWChem to NWChemEx: Evolving with the Computational Chemistry Landscape

et al. 2021

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“…In practice, prior information on the spectrum may also be required to select a suitable shift σ and normalise H. Well-studied strategies in the context of chemistry such as efficient approximations of the LDOS near the target [61,62] and iterative approaches [63] can be applied for shift selection, while standard VQE can be used to obtain extremal eigenvalues to normalize H.…”

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confidence: 99%

Scalable Quantum Computation of Highly Excited Eigenstates with Spectral Transforms

Shao-Hen¹,

Kwek²

2023

Preprint

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We propose a natural application of Quantum Linear Systems Problem (QLSP) solvers such as the HHL algorithm to efficiently prepare highly excited interior eigenstates of physical Hamiltonians in a variational manner. This is enabled by the efficient computation of inverse expectation values, taking advantage of the QLSP solvers' exponentially better scaling in problem size without concealing exponentially costly pre/post-processing steps that usually accompanies it. We detail implementations of this scheme for both fault-tolerant and near-term quantum computers, analyse their efficiency and implementability, and discuss applications and simulation results in many-body physics and quantum chemistry that demonstrate its superior effectiveness and scalability over existing approaches.

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Recent Progress in Evaluating the Kohn–Sham Map

Lin

Ying

2022

Density Functional Theory

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A Shift Selection Strategy for Parallel Shift-invert Spectrum Slicing in Symmetric Self-consistent Eigenvalue Computation

Cited by 5 publications

References 37 publications

From NWChem to NWChemEx: Evolving with the Computational Chemistry Landscape

From NWChem to NWChemEx: Evolving with the Computational Chemistry Landscape

Scalable Quantum Computation of Highly Excited Eigenstates with Spectral Transforms

Recent Progress in Evaluating the Kohn–Sham Map

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