Dichotomous array of chiral quantum corrals by a self-assembled nanoporous kagomé network

Florian Klappenberger; Dirk Kühne; Wolfgang Krenner; Iñaki Silanes; Andres Arnau; F. De Javier García Abajo; Svetlana Klyatskaya; Mario Ruben; Johannes V. Barth

doi:10.1021/nl901700b

Dichotomous array of chiral quantum corrals by a self-assembled nanoporous kagomé network

Florian Klappenberger, Dirk Kühne, Wolfgang Krenner, Iñaki Silanes, Andres Arnau, F. De Javier García Abajo, Svetlana Klyatskaya, Mario Ruben, Johannes V. Barth

Chair of Experimental Physics of Functional Spin-Systems

Research output: Contribution to journal › Article › peer-review

83 Scopus citations

Abstract

The confinement of surface-state electrons by a complex supramolecular network is studied with low-temperature scanning tunneling microscopy and rationalized by electronic structure calculations using a boundary element method. We focus on the self-assembly of dicarbonitrilesexiphenyl molecules on Ag(111) creating an open kagomé topology tessellating the surface into pores with different size and symmetry. This superlattice imposes a distinct surface electronic structure modulation, as observed by tunneling spectroscopy and thus acts as a dichotomous array of quantum corrals. The inhomogenous lateral electronic density distribution In the chiral cavities is reproduced by an effective pseudopotential model. Our results demonstrate the engineering of ensembles of elaborate quantum resonance states by molecular selfassembly at surfaces.

Original language	English
Pages (from-to)	3509-3514
Number of pages	6
Journal	Nano Letters
Volume	9
Issue number	10
DOIs	https://doi.org/10.1021/nl901700b
State	Published - 14 Oct 2009

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abstract = "The confinement of surface-state electrons by a complex supramolecular network is studied with low-temperature scanning tunneling microscopy and rationalized by electronic structure calculations using a boundary element method. We focus on the self-assembly of dicarbonitrilesexiphenyl molecules on Ag(111) creating an open kagom{\'e} topology tessellating the surface into pores with different size and symmetry. This superlattice imposes a distinct surface electronic structure modulation, as observed by tunneling spectroscopy and thus acts as a dichotomous array of quantum corrals. The inhomogenous lateral electronic density distribution In the chiral cavities is reproduced by an effective pseudopotential model. Our results demonstrate the engineering of ensembles of elaborate quantum resonance states by molecular selfassembly at surfaces.",

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T1 - Dichotomous array of chiral quantum corrals by a self-assembled nanoporous kagomé network

AU - Klappenberger, Florian

AU - Kühne, Dirk

AU - Krenner, Wolfgang

AU - Silanes, Iñaki

AU - Arnau, Andres

AU - De Javier García Abajo, F.

AU - Klyatskaya, Svetlana

AU - Ruben, Mario

AU - Barth, Johannes V.

PY - 2009/10/14

Y1 - 2009/10/14

N2 - The confinement of surface-state electrons by a complex supramolecular network is studied with low-temperature scanning tunneling microscopy and rationalized by electronic structure calculations using a boundary element method. We focus on the self-assembly of dicarbonitrilesexiphenyl molecules on Ag(111) creating an open kagomé topology tessellating the surface into pores with different size and symmetry. This superlattice imposes a distinct surface electronic structure modulation, as observed by tunneling spectroscopy and thus acts as a dichotomous array of quantum corrals. The inhomogenous lateral electronic density distribution In the chiral cavities is reproduced by an effective pseudopotential model. Our results demonstrate the engineering of ensembles of elaborate quantum resonance states by molecular selfassembly at surfaces.

AB - The confinement of surface-state electrons by a complex supramolecular network is studied with low-temperature scanning tunneling microscopy and rationalized by electronic structure calculations using a boundary element method. We focus on the self-assembly of dicarbonitrilesexiphenyl molecules on Ag(111) creating an open kagomé topology tessellating the surface into pores with different size and symmetry. This superlattice imposes a distinct surface electronic structure modulation, as observed by tunneling spectroscopy and thus acts as a dichotomous array of quantum corrals. The inhomogenous lateral electronic density distribution In the chiral cavities is reproduced by an effective pseudopotential model. Our results demonstrate the engineering of ensembles of elaborate quantum resonance states by molecular selfassembly at surfaces.

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Dichotomous array of chiral quantum corrals by a self-assembled nanoporous kagomé network

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