Photoemission spectroscopy using virtual photons emitted by positron sticking: a new probe of the top layer surface electronic structure

TL;DR

This paper introduces a novel spectroscopic technique using virtual photons emitted by positron sticking to measure the electronic structure of the top atomic layer, providing a non-destructive and surface-specific analysis method.

Contribution

The paper presents a new surface-sensitive spectroscopy method based on virtual photons from positron-surface interactions, enabling selective top-layer electronic structure measurement.

Findings

Electrons originate exclusively from the top atomic layer.

Kinetic energies reflect the surface density of states.

Technique is non-destructive and suitable for fragile 2D materials.

Abstract

We present a spectroscopic method which utilizes virtual photons to selectively measure the electronic structure of the top-most atomic layer. These virtual photons are created when incident positrons transition from vacuum states to bound surface states on the sample surface and can transfer sufficient energy to excite electrons into the vacuum. The short interaction range of the virtual photons restricts the penetration depth to approximately the Thomas-Fermi screening length. Measurements and analysis of the kinetic energies of the emitted electrons made on a single-layer of graphene deposited on Cu and on the clean Cu substrate shows that the ejected electrons originate exclusively from the top-most atomic layer. Moreover, we find that the kinetic energies of the emitted electrons reflect the density of states at the surface. These results demonstrate that this technique will be a complementary tool to existing spectroscopic techniques in determining the electronic structure of 2D materials and fragile systems due to the absence of subsurface contributions and probe-induced surface damage.