Litcius/Paper detail

Perspective: Simultaneous treatment of relativity, correlation, and <scp>QED</scp>

Wenjian Liu

2022Wiley Interdisciplinary Reviews Computational Molecular Science12 citationsDOI

Abstract

Abstract Electronic structure calculations of many‐electron systems should in principle treat relativistic, correlation, and quantum electrodynamics (QED) effects simultaneously to a high precision, so as to match experimental measurements as close as possible. While both relativistic and QED effects can readily be built into the many‐electron Hamiltonian, electron correlation is more difficult to describe due to the exponential growth of the number of parameters in the wave function. Compared with the spin‐free case, spin–orbit interaction results in the loss of spin symmetry and concomitant complex algebra, thereby rendering the treatment of electron correlation even more difficult. Possible solutions to these issues are highlighted here. This article is categorized under: Electronic Structure Theory &gt; Ab Initio Electronic Structure Methods

Topics & Concepts

Electronic correlationPhysicsTheory of relativityHamiltonian (control theory)Relativistic quantum chemistryElectronWave functionQuantum mechanicsElectronic structureRendering (computer graphics)Coupled clusterExponential functionTheoretical physicsQuantum electrodynamicsMathematicsComputer scienceMoleculeMathematical optimizationComputer graphics (images)Mathematical analysisAdvanced Chemical Physics StudiesMagnetism in coordination complexesQuantum and electron transport phenomena