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Controlling the preferential motion of chiral molecular walkers on a surface

Abbasi-Pérez, David; Sang, Hongqian; Pérez-García, Lluïsa; Floris, Andrea; Amabilino, David B.; Raval, Rasmita; Recio, J. Manuel; Kantorovich, Lev

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Authors

David Abbasi-Pérez

Hongqian Sang

Lluïsa Pérez-García

Andrea Floris

David B. Amabilino

Rasmita Raval

J. Manuel Recio

Lev Kantorovich



Abstract

Molecular walkers standing on two or more “feet” on an anisotropic periodic potential of a crystal surface may perform a one-dimensional Brownian motion at the surface-vacuum interface along a particular direction in which their mobility is the largest. In thermal equilibrium the molecules move with equal probabilities both ways along this direction, as expected from the detailed balance principle, well-known in chemical reactivity and in the theory of molecular motors. For molecules that possess an asymmetric potential energy surface (PES), we propose a generic method based on the application of a time-periodic external stimulus that would enable the molecules to move preferentially in a single direction thereby performing as Brownian ratchets. To illustrate this method, we consider a prototypical synthetic chiral molecular walker, the 1,3-bis(imidazol-1-ylmethyl)-5(1phenylethyl)benzene, diffusing on the anisotropic Cu(110) surface along the Cu rows. As unveiled by our kinetic Monte Carlo simulations based on the rates calculated using ab initio density functional theory, this molecule moves to the nearest equivalent lattice site via the so-called inchworm mechanism in which it steps first with the rear and then with the front foot. As a result, the molecule diffuses via a two-step mechanism, and due to its inherent asymmetry, the corresponding PES is also spatially asymmetric. Taking advantage of this fact, we show how the external stimulus can be tuned to separate molecules of different chirality, orientation and conformation. The consequences of these findings for molecular machines and the separation of enantiomers are also discussed.

Citation

Abbasi-Pérez, D., Sang, H., Pérez-García, L., Floris, A., Amabilino, D. B., Raval, R., …Kantorovich, L. (2019). Controlling the preferential motion of chiral molecular walkers on a surface. Chemical Science, 10(23), 5864-5874. https://doi.org/10.1039/c9sc01135h

Journal Article Type Article
Acceptance Date May 8, 2019
Online Publication Date May 14, 2019
Publication Date May 14, 2019
Deposit Date May 30, 2019
Publicly Available Date May 31, 2019
Journal Chemical Science
Print ISSN 2041-6520
Electronic ISSN 2041-6539
Publisher Royal Society of Chemistry
Peer Reviewed Peer Reviewed
Volume 10
Issue 23
Pages 5864-5874
DOI https://doi.org/10.1039/c9sc01135h
Keywords General Chemistry
Public URL https://nottingham-repository.worktribe.com/output/2109840
Publisher URL https://pubs.rsc.org/en/content/articlelanding/2019/SC/C9SC01135H#!divAbstract
Additional Information : This document is Similarity Check deposited; : Supplementary Information; : David Abbasi-Pérez (ORCID); : Hongqian Sang (ORCID); : Hongqian Sang (ResearcherID); : Lluïsa Pérez-García (ORCID); : Lluïsa Pérez-García (ResearcherID); : Andrea Floris (ORCID); : Andrea Floris (ResearcherID); : David B. Amabilino (ORCID); : David B. Amabilino (ResearcherID); : J. Manuel Recio (ORCID); : J. Manuel Recio (ResearcherID); : Lev Kantorovich (ORCID); : Lev Kantorovich (ResearcherID); : Single-blind; : Received 7 March 2019; Accepted 8 May 2019; Accepted Manuscript published 14 May 2019; Advance Article published 22 May 2019
Contract Date May 30, 2019

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