Issue 26, 2024

Imaging of ultrafast photoexcited electron dynamics in pentacene nanocrystals on a graphite substrate

Abstract

Understanding molecular film growth on substrates and the ultrafast electron dynamics at their interface is crucial for advancing next-generation organic electronics. We have focused on studying the ultrafast photoexcited electron dynamics in nanoscale organic crystals of an aromatic molecule, pentacene, on a two-dimensional material of graphite substrate. Through the use of time-resolved two-photon photoelectron emission microscopy (2P-PEEM), we have visualized the ultrafast lateral evolution of photoexcited electrons. By resonantly tuning the incident photon to excite pentacene molecules, polarization-dependent 2P-PEEM has revealed that pentacene nanocrystals (sub- to several μm) on the substrate exhibit a preferential orientation, in which a molecular π-orbital contacts the substrate in a “lying flat” orientation, facilitating electron transfer to the substrate. The time-resolved 2P-PEEM captures the motion of excited electrons in a femto- to pico-second timescale, clearly imaging the ultrafast charge transfer and lateral expansion two-dimensionally on the graphite substrate. Moreover, we found that the lying-flat molecular orientation of pentacene nanocrystals is transformable into a “standing-up” one through gentle heating up to 50 °C. These experimental insights using time-resolved 2P-PEEM will be highly valuable in enhancing the photofunctionalities of organic electronic devices by controlled molecular deposition.

Graphical abstract: Imaging of ultrafast photoexcited electron dynamics in pentacene nanocrystals on a graphite substrate

Supplementary files

Article information

Article type
Communication
Submitted
20 Feb 2024
Accepted
20 May 2024
First published
21 May 2024
This article is Open Access
Creative Commons BY license

Nanoscale, 2024,16, 12397-12405

Imaging of ultrafast photoexcited electron dynamics in pentacene nanocrystals on a graphite substrate

M. Shibuta and A. Nakajima, Nanoscale, 2024, 16, 12397 DOI: 10.1039/D4NR00720D

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