Exploring the bonding of large hydrocarbons on noble metals: Diindoperylene on Cu(111), Ag(111), and Au(111)

Bürker, Christoph; Ferri, Nicola; Tkatchenko, Alexandre; Gerlach, Alexander; Niederhausen, Jens; Hosokai, Takuya; Duhm, Steffen; Zegenhagen, J.; Koch, Norbert; Schreiber, Frank

doi:10.1103/physrevb.87.165443

Cited by 50 publications

(79 citation statements)

References 37 publications

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“…DIP has been studied extensively in monolayer on coinage metal surfaces [54][55][56]. The comparison between the equilibrium distance d C obtained with PBE + vdW surf and XSW experiments (Table I) shows an excellent agreement [11]. For what concerns E b , self-consistency leads to a tiny reduction (1.25%) of the PBE + vdW surf value.…”

Section: From Simple To Complex Interfacesmentioning

confidence: 55%

“…In this context, the long-range van der Waals (vdW) interactions-while absent in standard DFT exchangecorrelation (XC) functionals-have been proven of fundamental importance in determining the structure and the cohesive energies of layered systems, such as molecules adsorbed on metal surfaces [3,[7][8][9][10][11][12][13][14]. On the other hand, the long-range vdW energy represents only a small fraction (0.001%) of the total electronic energy for a wide range of systems [15], from small dimers (e.g., diatomic dimers, water dimer) to complex hybrid inorganic/organic systems, passing through large molecular systems and metal surfaces.…”

Section: Introductionmentioning

confidence: 99%

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Electronic charge rearrangement at metal/organic interfaces induced by weak van der Waals interactions

Ferri

Ambrosetti

Tkatchenko

2017

Phys. Rev. Materials

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Electronic charge rearrangements at interfaces between organic molecules and solid surfaces play a key role in a wide range of applications in catalysis, light-emitting diodes, single-molecule junctions, molecular sensors and switches, and photovoltaics. It is common to utilize electrostatics and Pauli pushback to control the interface electronic properties, while the ubiquitous van der Waals (vdW) interactions are often considered to have a negligible direct contribution (beyond the obvious structural relaxation). Here, we apply a fully self-consistent Tkatchenko-Scheffler vdW density functional to demonstrate that the weak vdW interactions can induce sizable charge rearrangements at hybrid metal/organic systems (HMOS). The complex vdW correlation potential smears out the interfacial electronic density, thereby reducing the charge transfer in HMOS, changes the interface work functions by up to 0.2 eV, and increases the interface dipole moment by up to 0.3 Debye. Our results suggest that vdW interactions should be considered as an additional control parameter in the design of hybrid interfaces with the desired electronic properties.

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Section: From Simple To Complex Interfacesmentioning

confidence: 55%

Section: Introductionmentioning

confidence: 99%

Electronic charge rearrangement at metal/organic interfaces induced by weak van der Waals interactions

Ferri

Ambrosetti

Tkatchenko

2017

Phys. Rev. Materials

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“…The vdW contribution to the binding energy of a diindenoperylene molecule (C 32 H 16 ) adsorbed on the Cu (111) surface is approximately 5.3 eV. 75 In this case, an error of 20% in the vdW coefficient would translate to an error of 1.0 eV in the equilibrium binding energyexceeding the energy of thermal fluctuations (kT) at room temperature by a factor of 35. We note that, in popular pairwise vdW corrections, vdW coefficients of molecules on metal surfaces can be overestimated by as much as 500%, because these approaches miss the complex polarization effects in the extended surface that are typically responsible for reducing the vdW coefficients of atoms in metals by 50−500% with respect to the free-atom values.…”

Section: Conceptual Understanding Of Vdw Interactions In Molecules Anmentioning

confidence: 99%

First-Principles Models for van der Waals Interactions in Molecules and Materials: Concepts, Theory, and Applications

2017

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Noncovalent van der Waals (vdW) or dispersion forces are ubiquitous in nature and influence the structure, stability, dynamics, and function of molecules and materials throughout chemistry, biology, physics, and materials science. These forces are quantum mechanical in origin and arise from electrostatic interactions between fluctuations in the electronic charge density. Here, we explore the conceptual and mathematical ingredients required for an exact treatment of vdW interactions, and present a systematic and unified framework for classifying the current first-principles vdW methods based on the adiabatic-connection fluctuation−dissipation (ACFD) theorem (namely the Rutgers−Chalmers vdW-DF, Vydrov−Van Voorhis (VV), exchange-hole dipole moment (XDM), Tkatchenko−Scheffler (TS), many-body dispersion (MBD), and random-phase approximation (RPA) approaches). Particular attention is paid to the intriguing nature of many-body vdW interactions, whose fundamental relevance has recently been highlighted in several landmark experiments. The performance of these models in predicting binding energetics as well as structural, electronic, and thermodynamic properties is connected with the theoretical concepts and provides a numerical summary of the state-of-the-art in the field. We conclude with a roadmap of the conceptual, methodological, practical, and numerical challenges that remain in obtaining a universally applicable and truly predictive vdW method for realistic molecular systems and materials.

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“…3,4 This technique has been applied to a number of molecules on various surfaces. [5][6][7][8][9][10][11][12][13] Here we report the use of XSW to determine the molecule-substrate distances in donor-acceptor molecular blends, which are not only highly relevant for many organic devices, but also have interfacial properties often differing from those of the corresponding single component layers. 14 In this work we provide a complete structural characterization of the first monolayer of a stoichiometric 1:1 donor-acceptor mixture assembled on Ag(111) and Cu(111) substrates.…”

Section: Introductionmentioning

confidence: 99%

Self-Assembly of Bicomponent Molecular Monolayers: Adsorption Height Changes and Their Consequences

et al. 2014

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Codeposition of two molecular species [CuPc (donor) and PFP (acceptor)] on noble metal (111) surfaces leads to the self-assembly of an ordered mixed layer with maximized donor-acceptor contact area. The main driving force behind this arrangement is assumed to be the intermolecular C-F ··· H-C hydrogen-bond interactions. Such interactions would be maximized for a coplanar molecular arrangement. However, precise measurement of molecule-substrate distances in the molecular mixture reveals significantly larger adsorption heights for PFP than for CuPc. Most surprisingly, instead of leveling to increase hydrogen bond interactions, the height difference is enhanced in mixed layers as compared to the heights found in single component CuPc and PFP layers, resulting in an overall reduced interaction with the underlying substrate. The influence of the increased height of PFP on the interface dipole is investigated through work function measurements.

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Exploring the bonding of large hydrocarbons on noble metals: Diindoperylene on Cu(111), Ag(111), and Au(111)

Cited by 50 publications

References 37 publications

Electronic charge rearrangement at metal/organic interfaces induced by weak van der Waals interactions

Electronic charge rearrangement at metal/organic interfaces induced by weak van der Waals interactions

First-Principles Models for van der Waals Interactions in Molecules and Materials: Concepts, Theory, and Applications

Self-Assembly of Bicomponent Molecular Monolayers: Adsorption Height Changes and Their Consequences

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