Polar Self-Organization of Ferroelectric Nematic-Liquid-Crystal Molecules on Atomically Flat Au(111) Surface

Alexandr A. Marchenko; Oleksiy L. Kapitanchuk; Yaroslava Yu Lopatina; Kostiantyn G. Nazarenko; Anton I. Senenko; Nathalie Katsonis; Vassili G. Nazarenko; Oleg D. Lavrentovich

doi:10.1103/PhysRevLett.132.098101

Polar Self-Organization of Ferroelectric Nematic-Liquid-Crystal Molecules on Atomically Flat Au(111) Surface

Alexandr A. Marchenko, Oleksiy L. Kapitanchuk, Yaroslava Yu Lopatina, Kostiantyn G. Nazarenko, Anton I. Senenko, Nathalie Katsonis, Vassili G. Nazarenko, Oleg D. Lavrentovich

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Abstract

Understanding nanoscale mechanisms responsible for the recently discovered ferroelectric nematics can be helped by direct visualization of self-assembly of strongly polar molecules. Here, we report on scanning tunneling microscopy studies of monomolecular layers of a ferroelectric nematic liquid crystal on a reconstructed Au(111) surface. The monolayers are obtained by deposition from a solution at ambient conditions. The adsorbed ferroelectric nematic molecules self-assemble into regular rows with tilted orientation, resembling a layered structure of a smectic C. Remarkably, each molecular dipole in this architecture is oriented along the same direction giving rise to polar ferroelectric ordering.

Original language	English
Article number	098101
Number of pages	6
Journal	Physical Review Letters
Volume	132
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevLett.132.098101
Publication status	Published - 1-Mar-2024

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Polar Self-Organization of Ferroelectric Nematic-Liquid-Crystal Molecules on Atomically Flat Au(111) SurfaceFinal publisher's version, 8.68 MBLicence: Taverne

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title = "Polar Self-Organization of Ferroelectric Nematic-Liquid-Crystal Molecules on Atomically Flat Au(111) Surface",

abstract = "Understanding nanoscale mechanisms responsible for the recently discovered ferroelectric nematics can be helped by direct visualization of self-assembly of strongly polar molecules. Here, we report on scanning tunneling microscopy studies of monomolecular layers of a ferroelectric nematic liquid crystal on a reconstructed Au(111) surface. The monolayers are obtained by deposition from a solution at ambient conditions. The adsorbed ferroelectric nematic molecules self-assemble into regular rows with tilted orientation, resembling a layered structure of a smectic C. Remarkably, each molecular dipole in this architecture is oriented along the same direction giving rise to polar ferroelectric ordering.",

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AU - Lopatina, Yaroslava Yu

AU - Nazarenko, Kostiantyn G.

AU - Senenko, Anton I.

AU - Katsonis, Nathalie

AU - Nazarenko, Vassili G.

AU - Lavrentovich, Oleg D.

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AB - Understanding nanoscale mechanisms responsible for the recently discovered ferroelectric nematics can be helped by direct visualization of self-assembly of strongly polar molecules. Here, we report on scanning tunneling microscopy studies of monomolecular layers of a ferroelectric nematic liquid crystal on a reconstructed Au(111) surface. The monolayers are obtained by deposition from a solution at ambient conditions. The adsorbed ferroelectric nematic molecules self-assemble into regular rows with tilted orientation, resembling a layered structure of a smectic C. Remarkably, each molecular dipole in this architecture is oriented along the same direction giving rise to polar ferroelectric ordering.

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Polar Self-Organization of Ferroelectric Nematic-Liquid-Crystal Molecules on Atomically Flat Au(111) Surface

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