Adsorption Behavior of Nonplanar Phthalocyanines: Competition of Different Adsorption Conformations

Wruß, Elisabeth; Hofmann, Oliver; Egger, David; Verwüster, Elisabeth; Gerlach, Alexander; Schreiber, Frank; Zojer, Egbert

doi:10.1021/acs.jpcc.6b00312

Cited by 12 publications

(16 citation statements)

References 55 publications

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“…Conversely, a significant impact of the GaCl dipole was obtained for intact molecules with upward-pointing Cl atoms. [208] Consequently, the measured work function allowed ruling out the latter configuration, but could not distinguish between the two former ones. This was possible only by an in-depth comparison between calculated [208] and measured [270] adsorption distances (which supported the existence of dechlorinated molecules).…”

Section: Fermi-level Pinningmentioning

confidence: 96%

“…Due to the larger average distance between the atoms in the substrate and those constituting the adsorbate it also causes a significantly reduced interaction energy. [208] In spite of the small van der Waals energy per atom, this effect is significant due to the resulting large van der Waals contact areas comprising a sizable number of atoms per molecule. In passing we note that for a priori less planar sub-phthalocyanines bearing polar ClB groups, the van der Waals attraction to the surface is even strong enough to essentially planarize the molecules with profound consequences also for the electronic properties of the adsorbate.…”

Section: Adsorption Of Polar Moleculesmentioning

confidence: 99%

“…This also modifies the adsorption-induced work-function change (albeit in a more complex way than expected based solely on the molecular dipoles, as will be discussed in Section 5.4). [208] Dechlorination processes have also been observed for chloro-boron-subphthalocyanine (ClB-subPc) on Cu(111), although there it has been argued that only the molecules landing in Cl-down orientation undergo the dechlorination. [213]…”

Section: Adsorption Of Polar Moleculesmentioning

confidence: 99%

“…Reproduced under the terms of the Creative Commons CC-BY license. [208] Copyright 2015, American Chemical Society. As the energy scale is aligned to the Fermi level, the latter also represents the work function of the system.…”

Section: Interfacial Charge Transfermentioning

confidence: 99%

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The Impact of Dipolar Layers on the Electronic Properties of Organic/Inorganic Hybrid Interfaces

Zojer

Taucher

Hofmann

2019

Adv Materials Inter

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138

168

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The presence of dipolar layers determines the functionality of most technologically relevant interfaces. The present contribution reviews how periodic dipole assemblies modify the properties of such interfaces through so‐called collective electrostatic effects. They impact the ionization energies and electron affinities of thin films, change the work function of metallic and semiconducting substrates, and determine the alignment of electronic states at interfaces. Dipolar layers originate either from the assembly of polar molecules or they arise from interfacial charge rearrangements triggered by the deposition of an adsorbate layer. Such charge rearrangements result from the omnipresent Pauli pushback caused by exchange interaction, from covalent bonds, or from charge transfer following the deposition of particularly electron rich (donors) or electron poor molecules (acceptors). A peculiarity of charge‐transfer interfaces is that they enter the realm of Fermi‐level pinning, where the sample work function becomes independent of the substrate and is solely determined by the electronic properties of the adsorbate. Beyond changing work functions and injection barriers, the presence of polar layers also modifies various other physical observables, like core‐level binding energies or tunneling currents in monolayer junctions. All these aspects suggest that polar layers can also be exploited for electrostatically designing the electronic properties of materials.

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Section: Fermi-level Pinningmentioning

confidence: 96%

Section: Adsorption Of Polar Moleculesmentioning

confidence: 99%

Section: Adsorption Of Polar Moleculesmentioning

confidence: 99%

Section: Interfacial Charge Transfermentioning

confidence: 99%

See 2 more Smart Citations

The Impact of Dipolar Layers on the Electronic Properties of Organic/Inorganic Hybrid Interfaces

Zojer

Taucher

Hofmann

2019

Adv Materials Inter

Self Cite

138

168

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show abstract

“…The NIXSW data were reinterpreted as consistent with this dissociation model. 11 Finally, a scanned-energy mode photoelectron diffraction (PhD) investigation of VOPc on Au(111) led to the conclusion that in this system, the V–O bond points out of the surface. 12…”

Section: Introductionmentioning

confidence: 99%

The Structure of VOPc on Cu(111): Does V═O Point Up, or Down, or Both?

et al. 2018

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The local structure of the nonplanar phthalocyanine, vanadyl phthalocyanine (VOPc), adsorbed on Cu(111) at a coverage of approximately one-half of a saturated molecular layer, has been investigated by a combination of normal-incidence X-ray standing waves (NIXSW), scanned-energy mode photoelectron diffraction (PhD), and density-functional theory (DFT), complemented by scanning tunnelling microscopy (STM). Qualitative assessment of the NIXSW data clearly shows that both “up” and “down” orientations of the molecule (with V=O pointing out of, and into, the surface) must coexist on the surface. O 1s PhD proves to be inconclusive regarding the molecular orientation. DFT calculations, using two different dispersion correction schemes, show good quantitative agreement with the NIXSW structural results for equal co-occupation of the two different molecular orientations and clearly favor the many body dispersion (MBD) method to deal with long-range dispersion forces. The calculated relative adsorption energies of the differently oriented molecules at the lowest coverage show a strong preference for the “up” orientation, but at higher local coverages, this energetic difference decreases, and mixed orientation phases are almost energetically equivalent to pure “up”-oriented phases. DFT-based Tersoff–Hamann simulations of STM topographs for the two orientations cast some light on the extent to which such images provide a reliable guide to molecular orientation.

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Electrostatically Designing Materials and Interfaces

Zojer

2024

Advanced Materials

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Collective electrostatic effects arise from the superposition of electrostatic potentials of periodically arranged (di)polar entities and are known to crucially impact the electronic structures of hybrid interfaces. Here, it is discussed, how they can be used outside the beaten paths of materials design for realizing systems with advanced and sometimes unprecedented properties. The versatility of the approach is demonstrated by applying electrostatic design not only to metal‐organic interfaces and adsorbed (complex) monolayers, but also to inter‐layer interfaces in van der Waals heterostructures, to polar metal‐organic frameworks (MOFs), and to the cylindrical pores of covalent organic frameworks (COFs). The presented design ideas are straightforward to simulate and especially for metal‐organic interfaces also their experimental implementation has been amply demonstrated. For van der Waals heterostructures, the needed building blocks are available, while the required assembly approaches are just being developed. Conversely, for MOFs the necessary growth techniques exist, but more work on advanced linker molecules is required. Finally, COF structures exist that contain pores decorated with polar groups, but the electrostatic impact of these groups has been largely ignored so far. All this suggest that the dawn of the age of electrostatic design is currently experienced with potential breakthroughs lying ahead.

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Adsorption Behavior of Nonplanar Phthalocyanines: Competition of Different Adsorption Conformations

Cited by 12 publications

References 55 publications

The Impact of Dipolar Layers on the Electronic Properties of Organic/Inorganic Hybrid Interfaces

The Impact of Dipolar Layers on the Electronic Properties of Organic/Inorganic Hybrid Interfaces

The Structure of VOPc on Cu(111): Does V═O Point Up, or Down, or Both?

Electrostatically Designing Materials and Interfaces

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