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@ARTICLE{Klein:894722,
author = {Klein, Benedikt P. and Morbec, Juliana M. and Franke,
Markus and Greulich, Katharina K. and Sachs, Malte and
Parhizkar, Shayan and Posseik, Francois and Schmid, Martin
and Hall, Samuel J. and Maurer, Reinhard J. and Meyer, Bernd
and Tonner, Ralf and Kumpf, Christian and Kratzer, Peter and
Gottfried, J. Michael},
title = {{M}olecule–{M}etal {B}ond of {A}lternant versus
{N}onalternant {A}romatic {S}ystems on {C}oinage {M}etal
{S}urfaces: {N}aphthalene versus {A}zulene on {A}g(111) and
{C}u(111)},
journal = {The journal of physical chemistry / C},
volume = {123},
number = {48},
issn = {1932-7455},
address = {Washington, DC},
publisher = {Soc.},
reportid = {FZJ-2021-03374},
pages = {29219 - 29230},
year = {2019},
abstract = {Interfaces between polycyclic π-electron systems and
metals play prominent roles in organic or graphene-based
(opto)electronic devices, in which performance-related
parameters depend critically on the properties of
metal/semiconductor contacts. Here, we explore how the
topology of the π-electron system influences the bonding
and the electronic properties of the interface. We use
azulene as a model for nonalternant pentagon–heptagon
(5–7) ring pairs and compare it to its isomer naphthalene,
which represents the alternant 6–6 ring pair. Their
coverage-dependent interaction with Ag(111) and Cu(111)
surfaces was studied with the normal-incidence X-ray
standing wave (NIXSW) technique, near-edge X-ray absorption
fine structure (NEXAFS) spectroscopy, UV and X-ray
photoelectron spectroscopies (UPS and XPS), and density
functional theory (DFT). Coverage-dependent adsorption
heights and spectroscopic data reveal that azulene forms
shorter interfacial bonds than naphthalene and engages in
stronger electronic interactions with both surfaces. These
differences are more pronounced on Cu. Increasing coverages
lead to larger adsorption heights, indicating bond weakening
by intermolecular repulsion. The extensive DFT calculations
include dispersive interactions using (1) the DFT-D3 scheme,
(2) the vdWsurf correction based on DFT-TS, (3) a many-body
dispersion (MBD) correction scheme, and (4) the D3surf
scheme. All methods predict the adsorption heights
reasonably well with an average error below 0.1 Å. The
stronger bond of azulene is attributed to its nonalternant
topology, which results in a reduced highest occupied
molecular orbital (HOMO)–lowest occupied molecular orbital
(LUMO) gap and brings the LUMO energetically close to the
Fermi energy of the metal, causing stronger hybridization
with electronic states of the metal surfaces.},
cin = {PGI-3},
ddc = {530},
cid = {I:(DE-Juel1)PGI-3-20110106},
pnm = {5213 - Quantum Nanoscience (POF4-521) / DFG project
396769409 - Grundlagen der Photoemissionstomographie},
pid = {G:(DE-HGF)POF4-5213 / G:(GEPRIS)396769409},
typ = {PUB:(DE-HGF)16},
UT = {WOS:000501623100016},
doi = {10.1021/acs.jpcc.9b08824},
url = {https://juser.fz-juelich.de/record/894722},
}
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