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Numerical stability of time-dependent coupled-cluster methods for many-electron dynamics in intense laser pulses

Håkon Emil Kristiansen, Øyvind Sigmundson Schøyen, Simen Kvaal, Thomas Bondo Pedersen

2020The Journal of Chemical Physics33 citationsDOIOpen Access PDF

Abstract

We investigate the numerical stability of time-dependent coupled-cluster theory for many-electron dynamics in intense laser pulses, comparing two coupled-cluster formulations with full configuration interaction theory. Our numerical experiments show that orbital-adaptive time-dependent coupled-cluster doubles (OATDCCD) theory offers significantly improved stability compared with the conventional Hartree-Fock-based time-dependent coupled-cluster singles-and-doubles (TDCCSD) formulation. The improved stability stems from greatly reduced oscillations in the doubles amplitudes, which, in turn, can be traced to the dynamic biorthonormal reference determinants of OATDCCD theory. As long as these are good approximations to the Brueckner determinant, OATDCCD theory is numerically stable. We propose the reference weight as a diagnostic quantity to identify situations where the TDCCSD and OATDCCD theories become unstable.

Topics & Concepts

Stability (learning theory)Dynamics (music)PhysicsNumerical stabilityLaserNumerical analysisMathematicsStatistical physicsClassical mechanicsComputer simulationTrajectoryMechanicsWork (physics)Stability conditionsStability theoryInstabilityControl theory (sociology)Computational physicsNumerical modelsMathematical analysisQuantum electrodynamicsLaser-Matter Interactions and ApplicationsLaser-Plasma Interactions and DiagnosticsAdvanced Electron Microscopy Techniques and Applications
Numerical stability of time-dependent coupled-cluster methods for many-electron dynamics in intense laser pulses | Litcius