Spin-dependent metastable He ($2^3S$) atom scattering from ferromagnetic surfaces: Potential application to polarized-gas production

TL;DR

This study investigates how spin-polarized metastable helium atoms scatter from ferromagnetic surfaces, revealing spin-flip probabilities and potential for producing polarized gases through surface interactions.

Contribution

It provides the first detailed measurement of spin-dependent scattering of metastable helium from ferromagnetic surfaces, demonstrating spin preservation and flip probabilities.

Findings

Spin-flip scattering probability up to 0.1.

Higher survival probability when spins are parallel.

Non-polarized He* can become 10% spin-polarized after collision.

Abstract

A spin-polarized triplet metastable helium (He*) beam has been used as a probe for surface magnetism, but changes in the spin state during scattering from a surface remain unclear. In the present study, we explored this issue by constructing an apparatus that allows us to direct a spin-polarized He* beam to a surface and measure the spin polarization of He* scattered from the surface. Magnetic hexapoles were used for both the beam polarization and the spin analysis. The results of the spin-dependent He* scattering experiments on clean Fe$_3$O$_4$(100), H-terminated Fe$_3$O$_4$(100), benzene-adsorbed Fe$_3$O$_4$(100), and non-magnetic Cu(100) surfaces indicated that although the spin direction of He* was mostly preserved during scattering from these surfaces, spin-flop scattering of surviving He* occurred with a probability up to approximately 0.1. Our results showed that the survival probability was higher when the spins of He* and the Fe$_3$O$_4$(100) film were parallel, which can be understood based on the lower He* resonance ionization rate for this spin orientation. Based on our findings, we estimate that a non-polarized He* gas becomes 10% spin-polarized after a single collision with a clean Fe$_3$O$_4$(100) surface.