4-2.7). The resultant values were within the applicable range for dielectric materials in integrated circuits. (C) 2011 Wiley Periodicals, Inc. J Appl Polym Sci 121: 3192-3200,

2011″
“Solution processed multilayer polymer light-emitting diodes (PLEDs) based on different molecular weight host have been investigated. A PLED based on high molecular weight poly (vinyl carbazole) PVKH and low molecular weight poly (vinyl carbazole) PVKL, doped with iridium, tris (2-phenylpyidine) Ir(ppy)(3) as a host-guest emitting layer (EML), shows a dramatic increase in device efficiency. When the PVKH was used as a hole transport electron blocking layer (HT-EBL), effective electron blocking was achieved, which leads to an increase exciton www.selleckchem.com/products/prt062607-p505-15-hcl.html population in the phosphorescent zone. The use of low molecular weight PVKL as a host material in the top layer prevents barrier formation LY294002 clinical trial for hole transport from the poly(3,4-ethylenedioxy-thiophene) (PEDOT)-EBL to the EML. External quantum efficiency of 11%, current efficiencies of 38 cd/A, power efficiency of 13 lm/W and brightness

of 7000 cd/m(2), were obtained. The effect of the PVKH layer on the electrical and optical device characteristics was investigated. Simulation of the optical outcoupling using SETFOS 3.1 software is in agreed with the observed results and allowed us to predict the emissive dipole location and distribution in the EML layer. The effect of the PVKH on the exciton quenching by the electrodes was also investigated using time resolved fluorescence photon counting, which indicates weak exciton quenching by the PEDOT layer and the device enhancement predominantly achieved by exciton confinement in the emissive layer. (C) 2011 American Institute of Physics. [doi: 10.1063/1.3569831]“
“A high level of robustness against gene deletion is observed in many organisms. However, it is

still not clear which biochemical features underline this robustness and how these are acquired during evolution. One hypothesis, specific to metabolic networks, is that robustness emerges as a byproduct of selection for biomass production in different environments. To test this hypothesis we performed evolutionary simulations of metabolic networks under stable and fluctuating environments. We find that networks Nepicastat order evolved under the latter scenario can better tolerate single gene deletion in specific environments. Such robustness is underlined by an increased number of independent fluxes and multifunctional enzymes in the evolved networks. Observed robustness in networks evolved under fluctuating environments was “”apparent,”" in the sense that it decreased significantly as we tested effects of gene deletions under all environments experienced during evolution. Furthermore, when we continued evolution of these networks under a stable environment, we found that any robustness they had acquired was completely lost.