Depolarization of Spin-Polarized Hydrogen via Collisions with Chlorine Atoms at Ultrahigh Density

TL;DR

This study investigates the depolarization mechanisms of spin-polarized hydrogen at ultrahigh densities, providing key collision cross-section data and exploring applications in advanced physics fields.

Contribution

It presents the first measurement of hydrogen-chlorine depolarization cross-section at densities up to 10^{20} cm^{-3}, advancing understanding of high-density spin polarization.

Findings

Depolarization cross-section for HCl collisions is 7(2) x 10^{-17}cm^2.

Achieved spin-polarized hydrogen densities up to 10^{20} cm^{-3}.

Identified conditions for reaching ultrahigh-density spin-polarized gases.

Abstract

Recently, the production of ultrahigh-density (~10^{19}cm^{-3}) spin-polarized deuterium (SPD) atoms was demonstrated, from the photodissociation of deuterium iodide, but the upper density limit was not determined. Here, we present studies of spin-polarized hydrogen (SPH) densities up to 10^{20} cm^{-3}, by photodissociating 5 bar of hydrogen chloride with a focused 213 nm, 150 ps laser pulse. We extract the depolarization cross-section of hydrogen and chlorine atom collisions, which is the main depolarization mechanism at this high-density regime, to be {\sigma}_{HCl} = 7(2) x 10^{-17}cm^2. We discuss the conditions under which the ultrahigh SPH and SPD densities can be reached, and the potential applications to ultrafast magnetometry, laser-ion acceleration, and tests of polarized nuclear fusion.