Your search keyword '"Frank Scholz"' showing total 3 results

1. Organic Dipole Layers for Ultralow Work Function Electrodes

Author

Rene Wirtz, Silvia Rosselli, Vadim Rodin, Frank Scholz, Deqing Gao, Florian von Wrochem, Nikolaus Knorr, Zoi Karipidou, William E. Ford, Kodo Ogasawara, and Gabriele Nelles

Subjects

Organic electronics, Materials science, business.industry, Fermi level, General Engineering, Analytical chemistry, General Physics and Astronomy, engineering.material, Organic semiconductor, symbols.namesake, Dipole, Electrode, engineering, symbols, Optoelectronics, General Materials Science, Noble metal, Work function, business, Diode

Abstract

The alignment of the electrode Fermi level with the valence or conduction bands of organic semiconductors is a key parameter controlling the efficiency of organic light-emitting diodes, solar cells, and printed circuits. Here, we introduce a class of organic molecules that form highly robust dipole layers, capable of shifting the work function of noble metals (Au and Ag) down to 3.1 eV, that is, ∼1 eV lower than previously reported self-assembled monolayers. The physics behind the considerable interface dipole is elucidated by means of photoemission spectroscopy and density functional theory calculations, and a polymer diode exclusively based on the surface modification of a single electrode in a symmetric, two-terminal Au/poly(3-hexylthiophene)/Au junction is presented. The diode exhibits the remarkable rectification ratio of ∼2·10(3), showing high reproducibility, durability (3 years), and excellent electrical stability. With this evidence, noble metal electrodes with work function values comparable to that of standard cathode materials used in optoelectronic applications are demonstrated.

Published

2014

2. Conductance Modulation in Tetraaniline Monolayers by HCl-Doping and by Field-Enhanced Dissociation of H2O

Author

William E. Ford, Florian von Wrochem, Gabriele Nelles, Frank Scholz, and Deqing Gao

Subjects

Organic electronics, Wien effect, Inorganic chemistry, Doping, General Engineering, General Physics and Astronomy, Conductance, Photochemistry, Dissociation (chemistry), chemistry.chemical_compound, chemistry, Polyaniline, Monolayer, General Materials Science, Thin film

Abstract

Oligoanilines are interesting candidates for organic electronics, as their conductivity can be varied by several orders of magnitude upon protonic doping. Here we demonstrate that tetraaniline self-assembled monolayers exhibit an unprecedented conductance on/off ratio of ∼710 (at +1 V) upon doping of the layers from the emeraldine base to the emeraldine salt form. Furthermore, a pronounced asymmetry in the current–voltage characteristics indicates dynamic doping of the tetraaniline layer by protons generated through field-enhanced dissociation of water molecules, a phenomenon known as the second Wien effect. These results point toward oligoanilines as promising substitutes for polyaniline layers in next-generation thin film devices.

Published

2013

3. Conductance modulation in tetraaniline monolayers by HCl-doping and by field-enhanced dissociation of H₂O

Author

William E, Ford, Deqing, Gao, Frank, Scholz, Gabriele, Nelles, and Florian, von Wrochem

Abstract

Oligoanilines are interesting candidates for organic electronics, as their conductivity can be varied by several orders of magnitude upon protonic doping. Here we demonstrate that tetraaniline self-assembled monolayers exhibit an unprecedented conductance on/off ratio of ∼710 (at +1 V) upon doping of the layers from the emeraldine base to the emeraldine salt form. Furthermore, a pronounced asymmetry in the current-voltage characteristics indicates dynamic doping of the tetraaniline layer by protons generated through field-enhanced dissociation of water molecules, a phenomenon known as the second Wien effect. These results point toward oligoanilines as promising substitutes for polyaniline layers in next-generation thin film devices.

Published

2013