Organic thin-film transistors: the passivation of the dielectric-pentacene interface by dipolar self-assembled monolayers.

In organic thin-film transistors (OTFTs), the conducting channel is located near the interface between the organic semiconductor and the oxide dielectric; this interface is crucial for transistor performance. Self-assembled monolayers (SAMs) on the interface reduce the negative influences of the oxide dielectric surface by decreasing the coupling of the carriers at the gate and the role of the active surface defects on transfer. In this paper, we show that SAMs carrying a dipole moment determine the OTFT performance by controlling the charge transfer between the oxide dielectric and the semiconductor. The charges introduced into the semiconductor by this transfer (i.e., residual carriers) lead to a threshold shift to positive values, as well as a decrease in the contact resistance and an increase in the apparent mobility. In this study, other effects of the SAMs, such as the gate potential shift in the channel or a direct reaction between semiconductor and SAM molecules, can be excluded as dominant processes.

Sublimation not an innocent technique: a case of bis-cyclometalated iridium emitter for OLED.

Isomerization of a neutral bis-cyclometalated iridium(III) complex has been observed for the first time during the preparation of vacuum-processed organic light-emitting devices (OLEDs) and reproduced in solution. Isolation of the isomer revealed a cis organization of the two pyridine rings of the cyclometalating ligands. Photophysical studies show very similar emission properties of the two isomers. However, due to in situ isomerization, it is only possible to prepare vacuum-processed OLED devices having a mixture of isomers.

Benzoic and aliphatic carboxylic acid monomolecular layers on oxidized GaAs surface as a tool for two-dimensional photonic crystal infiltration.

The possibility of using surface-adsorbed monolayers on oxidized GaAs single crystals is investigated to explore liquid crystal (LC) wettability and alignment. A technological process is developed to chemically activate the GaAs surface with a view to perform the infiltration of tunable two-dimensional (2-D) photonic crystals with LC materials. We demonstrate a vapor growth method to fabricate self-organized monolayers of carboxylated derivatives on plasma-activated surfaces. Our monolayers strongly increase the wettability of liquid crystal surfaces and may be helpful in achieving the infiltration of 2-D GaAs photonic crystals. Two types of molecular families were studied in this work: benzoic acids and fatty acids. Para-substituted benzoic acids with a wide range of electrical dipoles allow adsorption to be followed by measuring the surface potential of the grafted substrates using the Kelvin probe technique. These model compounds yield important information on the grafting conditions and the stability of the layers. Surface-adsorbed fatty acids are well-known to produce hydrophobic surfaces. The water contact angles measured on modified GaAs surfaces are equivalent to the ones measured on classical alkanethiol layers on gold.