Cluster superlattice membranes

Pantelis Bampoulis; Tobias Hartl; Moritz Will; Davor Čapeta; Rajendra Singh; Daniel Scheinecker; Virginia Boix de la Cruz; Sophia Dellmann; Paolo Lacovig; Silvano Lizzit; Boris V. Senkovskiy; Alexander Grüneis; Marko Kralj; Jan Knudsen; Jani Kotakoski; Thomas Michely

doi:10.1021/acsnano.0c05740

Cluster superlattice membranes

Pantelis Bampoulis^*, Tobias Hartl, Moritz Will, Davor Čapeta, Rajendra Singh, Daniel Scheinecker, Virginia Boix de la Cruz, Sophia Dellmann, Paolo Lacovig, Silvano Lizzit, Boris V. Senkovskiy, Alexander Grüneis, Marko Kralj, Jan Knudsen, Jani Kotakoski, Thomas Michely

^*Corresponding author for this work

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

8 Citations (Scopus)

Abstract

Cluster superlattice membranes consist of a twodimensional hexagonal lattice of similar-sized nanoclusters sandwiched between single-crystal graphene and an amorphous carbon matrix. The fabrication process involves three main steps, the templated selforganization of a metal cluster superlattice on epitaxial graphene on Ir(111), conformal embedding in an amorphous carbon matrix, and subsequent lift-off from the Ir(111) substrate. The mechanical stability provided by the carbon-graphene matrix makes the membrane stable as a free-standing material and enables transfer to other substrates. The fabrication procedure can be applied to a wide variety of cluster materials and cluster sizes from the single-atom limit to clusters of a few hundred atoms, as well as other twodimensional layer/host matrix combinations. The versatility of the membrane composition, its mechanical stability, and the simplicity of the transfer procedure make cluster superlattice membranes a promising material in catalysis, magnetism, energy conversion, and optoelectronics.

Original language	English
Pages (from-to)	13629-13637
Number of pages	9
Journal	ACS nano
Volume	14
Issue number	10
DOIs	https://doi.org/10.1021/acsnano.0c05740
Publication status	Published - 27 Oct 2020
Externally published	Yes

Keywords

n/a OA procedure
Membranes
Moire
Nanocluster superlattices
Two-dimensional materials
Graphene

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10.1021/acsnano.0c05740

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title = "Cluster superlattice membranes",

abstract = "Cluster superlattice membranes consist of a twodimensional hexagonal lattice of similar-sized nanoclusters sandwiched between single-crystal graphene and an amorphous carbon matrix. The fabrication process involves three main steps, the templated selforganization of a metal cluster superlattice on epitaxial graphene on Ir(111), conformal embedding in an amorphous carbon matrix, and subsequent lift-off from the Ir(111) substrate. The mechanical stability provided by the carbon-graphene matrix makes the membrane stable as a free-standing material and enables transfer to other substrates. The fabrication procedure can be applied to a wide variety of cluster materials and cluster sizes from the single-atom limit to clusters of a few hundred atoms, as well as other twodimensional layer/host matrix combinations. The versatility of the membrane composition, its mechanical stability, and the simplicity of the transfer procedure make cluster superlattice membranes a promising material in catalysis, magnetism, energy conversion, and optoelectronics.",

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author = "Pantelis Bampoulis and Tobias Hartl and Moritz Will and Davor {\v C}apeta and Rajendra Singh and Daniel Scheinecker and {Boix de la Cruz}, Virginia and Sophia Dellmann and Paolo Lacovig and Silvano Lizzit and Senkovskiy, {Boris V.} and Alexander Gr{\"u}neis and Marko Kralj and Jan Knudsen and Jani Kotakoski and Thomas Michely",

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year = "2020",

month = oct,

day = "27",

doi = "10.1021/acsnano.0c05740",

language = "English",

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T1 - Cluster superlattice membranes

AU - Bampoulis, Pantelis

AU - Hartl, Tobias

AU - Will, Moritz

AU - Čapeta, Davor

AU - Singh, Rajendra

AU - Scheinecker, Daniel

AU - Boix de la Cruz, Virginia

AU - Dellmann, Sophia

AU - Lacovig, Paolo

AU - Lizzit, Silvano

AU - Senkovskiy, Boris V.

AU - Grüneis, Alexander

AU - Kralj, Marko

AU - Knudsen, Jan

AU - Kotakoski, Jani

AU - Michely, Thomas

PY - 2020/10/27

Y1 - 2020/10/27

N2 - Cluster superlattice membranes consist of a twodimensional hexagonal lattice of similar-sized nanoclusters sandwiched between single-crystal graphene and an amorphous carbon matrix. The fabrication process involves three main steps, the templated selforganization of a metal cluster superlattice on epitaxial graphene on Ir(111), conformal embedding in an amorphous carbon matrix, and subsequent lift-off from the Ir(111) substrate. The mechanical stability provided by the carbon-graphene matrix makes the membrane stable as a free-standing material and enables transfer to other substrates. The fabrication procedure can be applied to a wide variety of cluster materials and cluster sizes from the single-atom limit to clusters of a few hundred atoms, as well as other twodimensional layer/host matrix combinations. The versatility of the membrane composition, its mechanical stability, and the simplicity of the transfer procedure make cluster superlattice membranes a promising material in catalysis, magnetism, energy conversion, and optoelectronics.

AB - Cluster superlattice membranes consist of a twodimensional hexagonal lattice of similar-sized nanoclusters sandwiched between single-crystal graphene and an amorphous carbon matrix. The fabrication process involves three main steps, the templated selforganization of a metal cluster superlattice on epitaxial graphene on Ir(111), conformal embedding in an amorphous carbon matrix, and subsequent lift-off from the Ir(111) substrate. The mechanical stability provided by the carbon-graphene matrix makes the membrane stable as a free-standing material and enables transfer to other substrates. The fabrication procedure can be applied to a wide variety of cluster materials and cluster sizes from the single-atom limit to clusters of a few hundred atoms, as well as other twodimensional layer/host matrix combinations. The versatility of the membrane composition, its mechanical stability, and the simplicity of the transfer procedure make cluster superlattice membranes a promising material in catalysis, magnetism, energy conversion, and optoelectronics.

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KW - Membranes

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KW - Nanocluster superlattices

KW - Two-dimensional materials

KW - Graphene

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JO - ACS nano

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Cluster superlattice membranes

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Keywords

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