Photoionization of temperature-controlled nanoparticles in a beam: Accurate and efficient determination of ionization energies and work functions

TL;DR

This study presents a precise and efficient method for determining ionization energies and work functions of temperature-controlled alkali metal nanoparticles in a beam using photoionization yield curves and Fowler function fitting.

Contribution

It introduces an experimental setup combining temperature-controlled nanoparticle production with automated photoionization measurements and a universal Fowler function fit for accurate electronic property determination.

Findings

Ionization energies measured with ~0.2% precision.

Work functions of nanoparticles accurately derived.

Method enables analysis of electronic and thermal properties.

Abstract

A beam of free alkali metal nanoparticles is produced by a condensation source, passed through a thermalizing tube adjustable over a broad temperature range, and ionized by tunable light. High stability of the particle flux and an automated data acquisition routine allow efficient collection of photoionization yield curves. A careful fit of the data to the universal Fowler function makes it possible to obtain nanoparticle ionization energies, and from those, the metal work functions, with $\sim$0.2% precision. The experimental arrangement, nanoparticle thermalization rates, and ionization threshold analysis are described in detail. The use of ultrapure and temperature-controlled gas-phase nanoparticles facilitates the analysis of electronic properties, such as work functions, and of their interplay with thermal lattice dynamics.