Tracing orbital images on ultrafast time scales

TL;DR

This paper introduces a femtosecond pump-probe technique combining high harmonic generation and momentum microscopy to visualize ultrafast electron dynamics in molecular orbitals in momentum space.

Contribution

It presents the first experimental method to track the real-time momentum-space evolution of unoccupied molecular orbitals during ultrafast processes.

Findings

Successful measurement of transient electron momentum distributions

Observation of ultrafast electron motion in molecules

Linking excited state dynamics to real-space pathways

Abstract

Frontier orbitals, i.e., the highest occupied and lowest unoccupied orbitals of a molecule, generally determine molecular properties, such as chemical bonding and reactivities. Consequently, there has been a lot of interest in measuring them, despite the fact that, strictly speaking, they are not quantum-mechanical observables. Yet, with photoemission tomography a powerful technique has recently been introduced by which the electron distribution in orbitals of molecules adsorbed at surfaces can be imaged in momentum space. This has even been used for the identification of reaction intermediates in surface reactions. However, so far it has been impossible to follow an orbital's momentum-space dynamics in time, for example through an excitation process or a chemical reaction. Here, we report a key step in this direction: we combine time-resolved photoemission employing high laser harmonics and a recently developed momentum microscope to establish a tomographic, femtosecond pump-probe experiment of unoccupied molecular orbitals. Specifically, we measure the full momentum-space distribution of transiently excited electrons. Because in molecules this momentum-space distribution is closely linked to orbital shapes, our experiment offers the extraordinary possibility to observe ultrafast electron motion in time and space. This enables us to connect their excited states dynamics to specific real-space excitation pathways.