Your search keyword '"Quantized cluster charging"' showing total 2 results

1. Charge Transport with Single Molecules – An Electrochemical Approach

Author

Chen Li, Artem Mishchenko, Ilya Pobelov, and Thomas Wandlowski

Subjects

Electrolyte gating, Quantized cluster charging, Single molecule electron transport, Stm-based break junction, Chemistry, QD1-999

Abstract

After an introduction and brief review of charge transport in nanoscale molecular systems we report on experimental studies in gold | (single) molecule | gold junctions at solid | liquid interfaces employing a scanning tunneling microscopy (STM)-based 'break junction' technique. We demonstrate attempts in developing basic relationships between molecular structure, conductance properties and nanoscale electrochemical concepts based on four case studies from our own work. In experiments with ?, ?-alkanedithiol and biphenyldithiol molecular junctions we address the role of sulfur-gold couplings and molecular conformation, such as gauche defects in the alkyl chains and the torsion angle between two phenyl rings. Combination with quantum chemistry calculations enabled a detailed molecular-level understanding of the electronic structure and transport characteristics of both systems. Employing the concept of 'electrolyte gating' with redox-active molecules, such as thiol-terminated derivatives of viologens (HS-6V6-SH or (HS-6V6)) we demonstrate the construction of symmetric and asymmetric active molecular junctions with transistor- or diode-like behavior upon polarization in an electrochemical environment. The experimental data could be represented quantitatively by the Kutznetsov/Ulstrup model assuming a two-step electron transfer with partial vibration relaxation. Finally, we show that surface-immobilized gold nanoparticles with a diameter of (2.4 ± 0.5) nm exhibit features of locally addressable multi-state electronic switching upon electrolyte gating, which appears to be reminiscent of a sequential charging through several 'oxidation/reduction states'.

Published

2010

2. Charge transport with single molecules--an electrochemical approach

Author

Thomas Wandlowski, Ilya Pobelov, Artem Mishchenko, and Chen Li

Subjects

Quantized cluster charging, Analytical chemistry, Electronic structure, Dihedral angle, Quantum chemistry, law.invention, Electron Transport, Electron transfer, Stm-based break junction, law, Electrochemistry, Molecule, Electrolyte gating, Sulfhydryl Compounds, Polarization (electrochemistry), QD1-999, Chemistry, General Medicine, General Chemistry, Chemical physics, Gold, Scanning tunneling microscope, Electronics, Break junction, Single molecule electron transport

Abstract

After an introduction and brief review of charge transport in nanoscale molecular systems we report on experimental studies in gold | (single) molecule | gold junctions at solid | liquid interfaces employing a scanning tunneling microscopy (STM)-based 'break junction' technique. We demonstrate attempts in developing basic relationships between molecular structure, conductance properties and nanoscale electrochemical concepts based on four case studies from our own work. In experiments with ?, ?-alkanedithiol and biphenyldithiol molecular junctions we address the role of sulfur-gold couplings and molecular conformation, such as gauche defects in the alkyl chains and the torsion angle between two phenyl rings. Combination with quantum chemistry calculations enabled a detailed molecular-level understanding of the electronic structure and transport characteristics of both systems. Employing the concept of 'electrolyte gating' with redox-active molecules, such as thiol-terminated derivatives of viologens (HS-6V6-SH or (HS-6V6)) we demonstrate the construction of symmetric and asymmetric active molecular junctions with transistor- or diode-like behavior upon polarization in an electrochemical environment. The experimental data could be represented quantitatively by the Kutznetsov/Ulstrup model assuming a two-step electron transfer with partial vibration relaxation. Finally, we show that surface-immobilized gold nanoparticles with a diameter of (2.4 ± 0.5) nm exhibit features of locally addressable multi-state electronic switching upon electrolyte gating, which appears to be reminiscent of a sequential charging through several 'oxidation/reduction states'.

Published

2010