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Accelerated multimodel Newton-type algorithms for faster convergence of ground and excited state coupled cluster equations

Eirik F. Kjønstad, Sarai D. Folkestad, Henrik Koch

2020The Journal of Chemical Physics11 citationsDOIOpen Access PDF

Abstract

We introduce a multimodel approach to solve coupled cluster equations, employing a quasi-Newton algorithm for the ground state and an Olsen algorithm for the excited states. In these algorithms, both of which can be viewed as Newton algorithms, the Jacobian matrix of a lower level coupled cluster model is used in Newton equations associated with the target model. Improvements in convergence then imply savings for sufficiently large molecular systems, since the computational cost of macroiterations scales more steeply with system size than the cost of microiterations. The multimodel approach is suitable when there is a lower level Jacobian matrix that is much more accurate than the zeroth order approximation. Applying the approach to the CC3 equations, using the CCSD approximation of the Jacobian, we show that the time spent to determine the ground and valence excited states can be significantly reduced. We also find improved convergence for core excited states, indicating that similar savings will be obtained with an explicit implementation of the core-valence separated CCSD Jacobian transformation.

Topics & Concepts

Jacobian matrix and determinantExcited stateConvergence (economics)Coupled clusterGround stateAlgorithmMatrix (chemical analysis)Cluster (spacecraft)Applied mathematicsMathematicsRate of convergenceA priori and a posterioriState (computer science)Newton's methodComputer sciencePhysicsMathematical optimizationIterative methodStatistical physicsAdvanced Chemical Physics StudiesMachine Learning in Materials ScienceAdvanced Physical and Chemical Molecular Interactions
Accelerated multimodel Newton-type algorithms for faster convergence of ground and excited state coupled cluster equations | Litcius