Abstract
The ability to access carrier dynamics selectively on material surfaces with high spatial and temporal control in a photo-induced reaction is a particularly challenging task that can only be achieved by applying four-dimensional ultrafast electron microscopy (4D UEM). For this purpose, we established and developed the second generation of four-dimensional scanning ultrafast electron microscopy (4D S-UEM) at KAUST and demonstrate the ability to take time-resolved secondary electrons images (snapshots) of material surfaces with 650 fs and ~ 5 nm temporal and spatial resolutions, respectively. In this method, the surface of the photoactive materials is excited by a clocking optical pulse and the photo-induced changes will be imaged using a pulsed primary electron beam as a probe pulse, generating secondary electrons, which are emitted from the surface of the specimen in a manner that is sensitive to the local electron/hole density. This method provides direct and controllable dynamical information regarding surface dynamics. For instance, we clearly demonstrate how the surface morphology, grains, defects and nanostructured features can significantly impact the overall dynamical processes on the surface of photoactive-materials. Moreover, we show that the energy loss and carrier spreading on the surfaces of InGaN nanowires can be achieved now in real space.. In another interesting work describes a breakthrough in mapping charge carrier dynamics on the surface of quaternary copper indium gallium selenide (CIGSe) nanocrystals (commonly used in solar and optoelectronic devices) using S-UEM. The time-resolved images provided by S-UEM clearly demonstrate how surface treatment with high band gap materials such as ZnS can control the overall carrier relaxation process on the surfaces of these materials. More specifically, SE images at different time delays of treated nanocrystal surfaces clearly indicate that the carrier dynamics is slowed down by at least factor of two, indicating that the density of the trap states is significantly reduced after surface treatment with ZnS inorganic layer.