Your search keyword '"Fredheim, Håkon Richard"' showing total 3 results

1. The time-dependent bivariational principle: Theoretical foundation for real-time propagation methods of coupled-cluster type

Author

Kvaal, Simen, Fredheim, Håkon Richard, Højlund, Mads Greisen, and Pedersen, Thomas Bondo

Subjects

Physics - Chemical Physics, Mathematical Physics, Quantum Physics

Abstract

Real-time propagation methods for chemistry and physics are invariably formulated using variational techniques. The time-dependent bivariational principle (TD-BIVP) is known to be the proper framework for coupled-cluster type methods, and is here studied from a differential geometric point of view. It is demonstrated how two distinct classical Hamilton's equations of motion arise from considering the real and imaginary parts of the action integral. The latter is new, and can in principle be used to develop novel propagation methods. Conservation laws and Poisson brackets are introduced, completing the analogy with classical mechanics. An overview of established real-time propagation methods is given in the context of our formulation of the TD-BIVP, namely time-dependent traditional coupled-cluster theory, orbital-adaptive coupled-cluster theory, time-dependent orthogonal optimized coupled-cluster theory, and equation-of-motion coupled cluster theory.

Published

2024

2. Magnus Expansion in Gauge Theories

Author

Fredheim, Håkon Richard, Ebrahimi-Fard, Kurusch, and Støvneng, Jon Andreas

Abstract

Noen uttrykk for løsningen på en ordinær differensiallikning utledes ved hjelp av en metode som innebærer Taylor-rekkeutvikling av vektorfeltet som definerer differensiallikningen. En generalisering av et kjent resultat utledes ved hjelp av denne fremgangsmåten. Følger av denne generaliseringen drøftes, og det vises hvordan disse gir ytterligere innsikt i løsningen på en beslektet mengde partielle differensiallikninger. To fysiske anvendelser av resultatene presenteres. Den første er en metode for å evaluere Feynman-integraler, og den andre er en metode for å finne svømmebanen til mikrober. Resultatene i denne oppgaven kan anvendes i mange fysiske fagfelt. Some expressions for the solution of an ordinary differential equation (ODE) are derived. The method used involves Taylor expanding the vector field defining the ODE. A generalization of a known result is derived taking this approach. Consequences of this generalization are elaborated upon and are shown to produce further insights into the solution of a related set of partial differential equations. Two physical applications of the results are presented. The first is a method for evaluating Feynman integrals, the second is a method for finding the path of swimming microbes. The results of this thesis have applications in many fields of Physics.

Published

2022

3. Ingen tittel

Author

Fredheim, Håkon Richard, Ebrahimi-Fard, Kurusch, and Støvneng, Jon Andreas

Published

2022