A three-beam setup for coherently controlling nuclear state population

TL;DR

This paper proposes a three-beam x-ray laser setup to coherently control nuclear state populations using stimulated Raman adiabatic passage, addressing current laser frequency limitations and optimizing experimental parameters.

Contribution

It introduces a systematic approach for implementing a three-beam setup to achieve coherent nuclear population transfer, including tolerance analysis and resonance conditions.

Findings

Optimized pulse sequences and intensities for nuclear state control.

Tolerance analysis for beam divergence and nuclear velocity spread.

A two-photon resonance condition reduces experimental strictness.

Abstract

The controlled transfer of nuclear state population using two x-ray laser pulses is investigated theoretically. The laser pulses drive two nuclear transitions in a nuclear three-level system facilitating coherent population transfer via the quantum optics technique of stimulated Raman adiabatic passage. To overcome present limitations of the x-ray laser frequency, we envisage accelerated nuclei interacting with two copropagating or crossed x-ray laser pulses in a three-beam setup. We present a systematic study of this setup providing both pulse temporal sequence and laser pulse intensity for optimized control of the nuclear state population. The tolerance for geometrical parameters such as laser beam divergence of the three-beam setup as well as for the velocity spread of the nuclear beam are studied and a two-photon resonance condition to account for experimental uncertainties is deduced. This additional condition gives a less strict requirement for the experimental implementation of the three-beam setup. Present experimental state of the art and future prospects are discussed.