Study of the adiabatic passage in tripod atomic systems in terms of the Riemannian geometry of the Bloch sphere

TL;DR

This paper uses Riemannian geometry to analyze adiabatic passage in tripod atomic systems, deriving optimal laser pulse sequences for high-fidelity quantum state transfer with minimal infidelity.

Contribution

It introduces a geometric interpretation of adiabatic passage in tripod systems and derives analytical optimal pulse sequences for efficient quantum state transfer.

Findings

Achieves infidelity of 10^{-7} with high adiabaticity parameter

Provides analytical formulas for optimal laser pulses

Demonstrates geometric approach's effectiveness in quantum control

Abstract

We present an analysis of the stimulated Raman adiabatic passage processes based on the methods of differential geometry. The present work was inspired by an excellent article by Bruce W. Shore et al. (R. G. Unanyan, B. W. Shore, and K. Bergmann Phys. Rev. A \textbf{59}, 2910 (1999)). We demonstrate how a purely geometric interpretation of the adiabatic passage in quantum tripod systems as a Riemannian parallel transport of the dark state vector along the Bloch sphere allows describing the evolution of the system for a given sequence of Stokes, pump and control laser excitation pulses. In combination with the Dykhne-Davis-Pechukas adiabaticity criterion and the minimax principle for circles on a sphere, this approach allows obtaining the analytical form of the optimal laser pulse sequences for a high fidelity tripod fractional STIRAP. In contrast to the conventional STIRAP in $\Lambda$-systems, the Gaussian approximations of the optimal laser pulse sequences allow reaching the infidelity of $10^{-7}$ for the adiabaticity parameter of $300$ without noticeable oscillatory or other detrimental effects on population transfer accuracy.