Berend Eggers scite author profile

Berend Eggers

4Publications

6Citation Statements Received

139Citation Statements Given

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107

135

Affiliations

University of Ulm, Institute of Organic Chemistry

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Optically Functionalized Grid‐Type Complexes by a Post‐Assembly Strategy

Eggers

Ziener

2018

Chemistry A European J

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Bisterpyridine-based grid complexes can serve as supramolecular three-dimensional scaffolds for the construction of larger molecular assemblies. Through functionalization of the ligand with azide groups, followed by self-assembly and metal-free Huisgen reactions, eight pyrene molecules can be attached to the grid structure in a single reaction step. The orientation and proximity provided by the scaffold allows for tuning the fluorescence properties of the dye molecules.

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Cyanophenyl vs. pyridine substituent: impact on the adlayer structure and formation on HOPG and Au(111)

Dai

Eggers

Metzler

et al. 2016

Phys. Chem. Chem. Phys.

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A new cyano substituted bis(terpyridine) derivative CN-BTP was synthesized and its adsorption on highly oriented pyrolytic graphite (HOPG) and Au(111) was investigated. CN-BTP is closely related to the previously investigated 2,4'-BTP, where the cyanophenyl groups are replaced by pyridine moieties. The scanning tunneling microscopy (STM) investigation of CN-BTP at the liquid|HOPG interface shows a highly ordered herringbone structure that is stabilized by double weak intermolecular C-HN hydrogen bonds, partially through the -CN substituents, which is different from the most stable square structure of 2,4'-BTP. The adsorption processes were investigated using cyclic voltammetry (CV) on Au(111) in a neutral phosphate buffer. A fast and full adlayer formation could be observed with CN-BTP, whereas an extremely slow process with 2,4'-BTP under the same conditions was found. Our data show that the CN substituents on BTP not only change the structure of the monolayer at the liquid|HOPG interface, but also accelerate the phase transition process in the electrolyte dramatically. This could be explained by the adlayer-substrate interactions, which is supported by DFT calculations. Our findings might be extended more generally to further pyridine comprising self-assembling molecules to fine-tune the adlayer structure and phase transition/adsorption kinetics by replacing pyridine by cyanophenyl moieties.

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Untersuchung von Obst, Gemüse and Konserven

Hanus¹,

Vořišek²,

Eggers³

et al. 1939

Fresenius, Zeitschrift f. anal. Chemie

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Funktionalisierung von Gitterkomplexen und Gitterkomplexliganden auf Oligopyridin-Basis

Eggers¹

2016

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Berend Eggers

Optically Functionalized Grid‐Type Complexes by a Post‐Assembly Strategy

Cyanophenyl vs. pyridine substituent: impact on the adlayer structure and formation on HOPG and Au(111)

Untersuchung von Obst, Gemüse and Konserven

Funktionalisierung von Gitterkomplexen und Gitterkomplexliganden auf Oligopyridin-Basis

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