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Characterization of individual molecular adsorption geometries by atomic force microscopy: Cu-TCPP on rutile TiO{sub 2} (110)

Functionalized materials consisting of inorganic substrates with organic adsorbates play an increasing role in emerging technologies like molecular electronics or hybrid photovoltaics. For such applications, the adsorption geometry of the molecules under operating conditions, e.g., ambient temperatu...

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Published in:	The Journal of chemical physics 2015-09, Vol.143 (9)
Main Authors:	Jöhr, Res, Hinaut, Antoine, Pawlak, Rémy, Saha, Santanu, Goedecker, Stefan, Meyer, Ernst, Glatzel, Thilo, Sadeghi, Ali, Such, Bartosz, Szymonski, Marek
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Language:	English
Subjects:	ADSORPTION AMBIENT TEMPERATURE ATOMIC FORCE MICROSCOPY COPPER DIPOLES ELECTRON TRANSFER INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY INTERFACES MOLECULES PHOTOELECTRON SPECTROSCOPY PHOTOVOLTAIC EFFECT PORPHYRINS POTENTIALS PROBES RESOLUTION RUTILE SCANNING TUNNELING MICROSCOPY SUBSTRATES SURFACES TEMPERATURE RANGE 0273-0400 K TITANIUM OXIDES
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creator	Jöhr, Res Hinaut, Antoine Pawlak, Rémy Saha, Santanu Goedecker, Stefan Meyer, Ernst Glatzel, Thilo Sadeghi, Ali Such, Bartosz Szymonski, Marek
description	Functionalized materials consisting of inorganic substrates with organic adsorbates play an increasing role in emerging technologies like molecular electronics or hybrid photovoltaics. For such applications, the adsorption geometry of the molecules under operating conditions, e.g., ambient temperature, is crucial because it influences the electronic properties of the interface, which in turn determine the device performance. So far detailed experimental characterization of adsorbates at room temperature has mainly been done using a combination of complementary methods like photoelectron spectroscopy together with scanning tunneling microscopy. However, this approach is limited to ensembles of adsorbates. In this paper, we show that the characterization of individual molecules at room temperature, comprising the determination of the adsorption configuration and the electrostatic interaction with the surface, can be achieved experimentally by atomic force microscopy (AFM) and Kelvin probe force microscopy (KPFM). We demonstrate this by identifying two different adsorption configurations of isolated copper(II) meso-tetra (4-carboxyphenyl) porphyrin (Cu-TCPP) on rutile TiO{sub 2} (110) in ultra-high vacuum. The local contact potential difference measured by KPFM indicates an interfacial dipole due to electron transfer from the Cu-TCPP to the TiO{sub 2}. The experimental results are verified by state-of-the-art first principles calculations. We note that the improvement of the AFM resolution, achieved in this work, is crucial for such accurate calculations. Therefore, high resolution AFM at room temperature is promising for significantly promoting the understanding of molecular adsorption.
doi_str_mv	10.1063/1.4929608
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source	American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list); AIP Journals (American Institute of Physics)
subjects	ADSORPTION AMBIENT TEMPERATURE ATOMIC FORCE MICROSCOPY COPPER DIPOLES ELECTRON TRANSFER INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY INTERFACES MOLECULES PHOTOELECTRON SPECTROSCOPY PHOTOVOLTAIC EFFECT PORPHYRINS POTENTIALS PROBES RESOLUTION RUTILE SCANNING TUNNELING MICROSCOPY SUBSTRATES SURFACES TEMPERATURE RANGE 0273-0400 K TITANIUM OXIDES
title	Characterization of individual molecular adsorption geometries by atomic force microscopy: Cu-TCPP on rutile TiO{sub 2} (110)
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