Thermal-Driven Formation of 2D Nanoporous Networks on Metal Surfaces

Lyu, Lu; Maniraj, M.; Mousavion, Sina; Becker, S.; Huang, Han; Aeschlimann, Martin; Stadtmüller, Benjamin

doi:10.1021/acs.jpcc.9b06327

Cited by 2 publications

(1 citation statement)

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“…We calculate the pair potential between the molecules using partial charges on each atom in the molecules obtained from the RASSCF calculation of the ground state of CuPc t-1 and the ionized state of CuPc + t1 (20). Such a pair-potential calculation was previously applied to similar molecular systems (22)(23)(24). As a result, it is found that depending on the initial in-plane orientation of the molecules relative to their unit cell (angles marked in Fig.…”

Section: Structural Dynamics From Wavefunction and Xpd Pattern Analysismentioning

confidence: 99%

Multiplex movie of concerted rotation of molecules on a 2D material

Scholz

Baumgärtner

Nozaki

et al. 2023

Preprint

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Function is dynamic and originates at atomic interfaces. Combining the degrees of freedom of molecules (1,2) with the peculiar properties of 2D quantum materials (3,4,5) can create novel functionality (6,7). Here, we report the manipulation and ultrafast imaging of a unidirectional gearing motion in molecules on a 2D quantum material. To visualize and disentangle the intertwined structural and electronic dynamics of such a hybrid interface, we record a ‘full molecular movie’ (8) by imaging the atomic positions (9,10), the evolution of the molecular orbital wavefunctions (11,12) and the modification of electronic states of the substrate (13). In a multimodal investigation in a single setup (14), we disentangle dynamics in valence and core electrons of both the molecule and the surface with femtosecond and sub-ångström precision. The ultrafast rotational motion is fueled by the transfer of hot holes into the molecules that results in “supercharging” of the film. As hot carriers move through the interface, we track a transient modification of the frontier molecular orbitals and observe a chiral symmetry breaking associated with local structural rearrangements. Our calculations show that the “supercharging” changes the interfacial potential energy landscape and triggers the gearing motion. The experiment offers all-in-one imaging of the electronic, molecular orbital, chemical and structural dynamics during the flow of charge and energy across the hybrid interface. Our approach provides detailed dynamical information on the mechanism underlying surface-adsorbed molecular gears and enables tailoring novel functionalities in hybrid active matter.

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Section: Structural Dynamics From Wavefunction and Xpd Pattern Analysismentioning

confidence: 99%