Concentration and Coverage Dependent Adlayer Structures: From Two-Dimensional Networks to Rotation in a Bearing

Meier, Christoph A.; Roos, Michael; Künzel, Daniela; Breitruck, A.; Hoster, Harry E.; Landfester, Katharina; Groß, Axel; Behm, R. J.; Ziener, Ulrich

doi:10.1021/jp910029z

Cited by 76 publications

(105 citation statements)

References 55 publications

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“…This behavior of 3,3′-BTP molecules is in stark contrast to that observed on HOPG, wherein well-ordered 2D patterns were monitored. [148] On EG/Ru(0001) the molecules exclusively occupied the 'valley' sites while most of the bright 'hill' sites remained vacant. This observation was found to be in good accordance with theoreti cal calculations, which revealed the difference in adsorption energy between 'valley' and 'hill' sites as high as ≈ 0.36 eV.…”

Section: Non-covalent Functionalization Of Graphene: Towards Structurmentioning

confidence: 99%

Supramolecular Approaches to Graphene: From Self‐Assembly to Molecule‐Assisted Liquid‐Phase Exfoliation

2016

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Graphene, a one-atom thick two-dimensional (2D) material, is at the core of an ever-growing research effort due to its combination of unique mechanical, thermal, optical and electrical properties. Two strategies are being pursued for the graphene production: the bottom-up and the top-down. The former relies on the use of covalent chemistry approaches on properly designed molecular building blocks undergoing chemical reaction to form 2D covalent networks. The latter occurs via exfoliation of bulk graphite into individual graphene sheets. Amongst the various types of exfoliations exploited so far, ultrasound-induced liquid-phase exfoliation (UILPE) is an attractive strategy, being extremely versatile, up-scalable and applicable to a variety of environments. In this review, we highlight the recent developments that have led to successful non-covalent functionalization of graphene and how the latter can be exploited to promote the process of molecule-assisted UILPE of graphite. The functionalization of graphene with non-covalently interacting molecules, both in dispersions as well as in dry films, represents a promising and modular approach to tune various physical and chemical properties of graphene, eventually conferring to such a 2D system a multifunctional nature.

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Section: Non-covalent Functionalization Of Graphene: Towards Structurmentioning

confidence: 99%

Supramolecular Approaches to Graphene: From Self‐Assembly to Molecule‐Assisted Liquid‐Phase Exfoliation

2016

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“…Careful control over concentration can aid in selecting a specific structure, especially when two or more polymorphs are possible that differ in packing density or adsorption energy [30][31][32][33][34][35]. One of the first examples of concentration-dependent self-assembly was discovered in the case of alkoxylated DBA derivatives [30].…”

Section: Role Of Concentrationmentioning

confidence: 99%

Principles of molecular assemblies leading to molecular nanostructures

Mali

Feyter

2013

Phil. Trans. R. Soc. A.

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Self-assembled physisorbed monolayers consist of regular two-dimensional arrays of molecules. Two-dimensional self-assembly of organic and metal–organic building blocks is a widely used strategy for nanoscale functionalization of surfaces. These supramolecular nanostructures are typically sustained by weak non-covalent forces such as van der Waals, electrostatic, metal–ligand, dipole–dipole and hydrogen bonding interactions. A wide variety of structurally very diverse monolayers have been fabricated under ambient conditions at the liquid–solid and air–solid interface or under ultra-high-vacuum (UHV) conditions at the UHV–solid interface. The outcome of the molecular self-assembly process depends on a variety of factors such as the nature of functional groups present on assembling molecules, the type of solvent, the temperature at which the molecules assemble and the concentration of the building blocks. The objective of this review is to provide a brief account of the progress in understanding various parameters affecting two-dimensional molecular self-assembly through illustration of some key examples from contemporary literature.

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“…The strong interaction here is just a consequence of the large size of the molecule, leading to the dominant contribution of the van der Waals interaction to the bonding, which keeps the molecule adsorbed on the surface up to temperatures above 500 K. [15] Furthermore, because of the nondirectional nature of the van der Waals interaction, the adsorption energy of BTP on graphite exhibits only a small corrugation, that is, it depends very weakly on the lateral position of the molecule. Hence, the particular arrangement of BTP molecules in an ordered supramolecular structure on graphite [2,27] is almost entirely determined by the formation of intermolecular hydrogen bonds. [11] In order to trace back the reason for the large discrepancy between force field calculations and experiment, we used the optimized geometry obtained from each force field for singlepoint DFT-D2 [6] energy calculations, that is, without any further structure optimization.…”

Section: à6mentioning

confidence: 99%

Adsorption of Supramolecular Building Blocks on Graphite: A Force Field and Density Functional Theory Study

et al. 2011

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Concentration and Coverage Dependent Adlayer Structures: From Two-Dimensional Networks to Rotation in a Bearing

Cited by 76 publications

References 55 publications

Supramolecular Approaches to Graphene: From Self‐Assembly to Molecule‐Assisted Liquid‐Phase Exfoliation

Supramolecular Approaches to Graphene: From Self‐Assembly to Molecule‐Assisted Liquid‐Phase Exfoliation

Principles of molecular assemblies leading to molecular nanostructures

Adsorption of Supramolecular Building Blocks on Graphite: A Force Field and Density Functional Theory Study

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