Biasing Enantiomorph Formation via Geometric Confinement: Nanocorrals for Chiral Induction at the Liquid–Solid Interface | Zendy

Johannes Seibel | Zendy; Lander Verstraete | Zendy; Brandon E. Hirsch | Zendy; Ana M. Bragança | Zendy; Steven De Feyter | Zendy

Open Access

Biasing Enantiomorph Formation via Geometric Confinement: Nanocorrals for Chiral Induction at the Liquid–Solid Interface

Author(s) -

Johannes Seibel,

Lander Verstraete,

Brandon E. Hirsch,

Ana M. Bragança,

Steven De Feyter

Publication year - 2018

Publication title -

journal of the american chemical society

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 7.115

H-Index - 612

eISSN - 1520-5126

pISSN - 0002-7863

DOI - 10.1021/jacs.8b04992

Subject(s) - chemistry , graphite , lithography , covalent bond , molecule , orientation (vector space) , nanotechnology , biasing , chemical physics , optoelectronics , organic chemistry , voltage , materials science , geometry , physics , mathematics , quantum mechanics

Nanocorrals created by scanning probe lithography on covalently modified graphite surfaces are used to induce a chiral bias in the enantiomorphic assembly of a prochiral molecule at the liquid/graphite interface. By controlling the orientation of the nanocorrals with respect to the underlying graphite surface, the nanocorral handedness can be freely chosen and thus a chiral bias in molecular self-assembly is created at an achiral surface solely by the scanning probe lithography process.

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