This review article provides a brief survey of materials, structures and current state-of-the-art
techniques used to measure the charge conduction characteristics of single molecules …

Photoswitching molecules are attractive candidates as organic materials for optoelectronics
applications because light impulses can switch them between states with different …

Charge transport through single diblock dipyrimidinyl diphenyl molecules consisting of a
donor and acceptor moiety was measured in the low-bias regime and as a function of bias at …

From its very start, one of the most intriguing motivations of molecular electronics is to
provide unique and low-cost solutions for electronic functions based on molecules, such as …

Hydrogen-bonded semiconductors stand among the next generation of electronic materials
thanks to their promising and versatile properties. Hydrogen-bonding has been proven to …

Electron transport through π–π stacked materials has been studied theoretically and
experimentally so far with versatile applications in mind. In this paper a novel π–π stacked …

Controlling charge transport through a single molecule junction, ie a single molecule
connected to source and drain electrodes, remains a long standing goal of molecular …

The field of molecular electronics is prompted by tremendous opportunities for using a single-
molecule and molecular monolayers as active components in integrated circuits. Until now …

The charge transport of 1, 4, 5, 8-naphthalene diimide (NDI)-based molecules is explored.
Experimental results show that the conductance of the TH-NDI molecular junction can be …

The formation of well-defined three-dimensional (3D) redox-active molecular nanostructures
at the electrode surfaces may open additional routes to achieve higher conductance in …