Consequences of Zeeman Degeneracy for van der Waals Blockade between Rydberg Atoms

TL;DR

This paper investigates how Zeeman degeneracies influence van der Waals interactions between Rydberg atoms, highlighting their impact on quantum information processing and identifying optimal conditions for effective blockade.

Contribution

It provides a comprehensive analysis of Zeeman degeneracy effects on Rydberg atom interactions, including explicit calculations and practical guidelines for quantum information applications.

Findings

Certain Zeeman level combinations have negligible interactions, making them unsuitable for blockade.

Identified promising angular momentum channels for effective blockade.

Quantitative estimates of van der Waals interactions for principal quantum numbers up to 100.

Abstract

We analyze the effects of Zeeman degeneracies on the long-range interactions between like Rydberg atoms, with particular emphasis on applications to quantum information processing using van der Waals blockade. We present a general analysis of how degeneracies affect the primary error sources in blockade experiments, emphasizing that blockade errors are sensitive primarily to the weakest possible atom-atom interactions between the degenerate states, not the mean interaction strength. We present explicit calculations of the van der Waals potentials in the limit where the fine-structure interaction is large compared to the atom-atom interactions. The results are presented for all potential angular momentum channels invoving s, p, and d states. For most channels there are one or more combinations of Zeeman levels that have extremely small dipole-dipole interactions and are therefore poor candidates for effective blockade experiments. Channels with promising properties are identified and discussed. We also present numerical calculations of Rb and Cs dipole matrix elements and relevant energy levels using quantum defect theory, allowing for convenient quantitative estimates of the van der Waals interactions to be made for principal quantum numbers up to 100. Finally, we combine the blockade and van der Waals results to quantitatively analyze the angular distribution of the blockade shift and its consequence for angular momentum channels and geometries of particular interest for blockade experiments with Rb.