Four-Dimensional Scaling of Dipole Polarizability in Quantum Systems

TL;DR

This paper introduces a universal four-dimensional scaling law for dipole polarizability in quantum systems, simplifying calculations across various systems and spectra by linking polarizability to a characteristic length and energy ratio.

Contribution

The study derives a universal four-dimensional scaling law for dipole polarizability applicable to diverse quantum systems, unifying previous scaling laws and enabling accurate predictions.

Findings

Universal 4D scaling law for polarizability derived

Accurate predictions for atoms, molecules, and periodic systems

Applicable across systems with different spectra and dimensions

Abstract

Polarizability is a key response property of physical and chemical systems, which has an impact on intermolecular interactions, spectroscopic observables, and vacuum polarization. The calculation of polarizability for quantum systems involves an infinite sum over all excited (bound and continuum) states, concealing the physical interpretation of polarization mechanisms and complicating the derivation of efficient response models. Approximate expressions for the dipole polarizability, $\alpha$, rely on different scaling laws $\alpha \propto$ $R^3$, $R^4$, or $R^7$, for various definitions of the system radius $R$. Here, we consider a range of single-particle quantum systems of varying spatial dimensionality and having qualitatively different spectra, demonstrating that their polarizability follows a universal four-dimensional scaling law $\alpha = C (4 \mu q^2/\hbar^2)L^4$, where $\mu$ and $q$ are the (effective) particle mass and charge, $C$ is a dimensionless excitation-energy ratio, and the characteristic length $L$ is defined via the $\mathcal{L}^2$-norm of the position operator. %The applicability of this unified formula is demonstrated by accurately predicting the dipole polarizability of 36 atoms and 1641 small organic~molecules. This unified formula is also applicable to many-particle systems, as shown by} accurately predicting the dipole polarizability of 36 atoms, 1641 small organic \rrr{molecules, and Bloch electrons in periodic systems.