Unusual reversibility in molecular break-up of PAHs: the case of pentacene dehydrogenation on Ir(111)

Davide Curcio; Emil Sierda; Monica Pozzo; Luca Bignardi; Luca Sbuelz; Paolo Lacovig; Silvano Lizzit; Dario Alfè; Alessandro Baraldi

doi:10.1039/d0sc03734f

Unusual reversibility in molecular break-up of PAHs: the case of pentacene dehydrogenation on Ir(111)

Chem Sci. 2020 Nov 3;12(1):170-178. doi: 10.1039/d0sc03734f.

Authors

Davide Curcio¹, Emil Sierda^{2

3}, Monica Pozzo^{4

5}, Luca Bignardi¹, Luca Sbuelz¹, Paolo Lacovig⁶, Silvano Lizzit⁶, Dario Alfè^{4

5

7}, Alessandro Baraldi^{1

6

8}

Affiliations

¹ Department of Physics, University of Trieste Via Valerio 2 34127 Trieste Italy alessandro.baraldi@elettra.eu +39 040 3758719.
² Department of Physics, University of Hamburg Jungiusstrasse 11 D-20355 Hamburg Germany.
³ Institute of Physics, Poznan University of Technology Piotrowo 3 60-965 Poznan Poland.
⁴ Department of Earth Sciences, Thomas Young Center, University College London 5 Gower Place London WC1E 6BS UK.
⁵ London Centre for Nanotechnology, Thomas Young Centre, University College London 17-19 Gordon Street London WC1H 0AH UK.
⁶ Elettra-Sincrotrone Trieste S.C.p.A. Strada Statale 14 - km 163.5 in AREA Science Park 34149 Trieste Italy.
⁷ Dipartimento di Fisica "Ettore Pancini", Università di Napoli "Federico II" Monte S. Angelo 80126 Napoli Italy.
⁸ IOM-CNR, Laboratorio TASC Strada Statale 14 - km 163.5 in AREA Science Park 34149 Trieste Italy.

Abstract

In this work, we characterize the adsorption of pentacene molecules on Ir(111) and their behaviour as a function of temperature. While room temperature adsorption preserves the molecular structure of the five benzene rings and the bonds between carbon and hydrogen atoms, we find that complete C-H molecular break up takes place between 450 K and 550 K, eventually resulting in the formation of small graphene islands at temperatures larger than 800 K. Most importantly a reversible temperature-induced dehydrogenation process is found when the system is annealed/cooled in a hydrogen atmosphere with a pressure higher than 5 × 10^-7 mbar. This novel process could have interesting implications for the synthesis of larger acenes and for the manipulation of graphene nanoribbon properties.