arrihizus can grow normally in 200 mg L(-1) uranium-contained medium. Optimum biosorption was observed at solution pH 4.0 and the maximum biosorption capacity (112.2 mg g(-1)) was obtained at initial U(VI) concentration of 200 mg L(-1). The biosorption process appeared to be temperature independent. Biosorption equilibrium was established within 90 min and the pseudo second-order BAY 80-6946 supplier model was found to fit accurately with the experimental data.
FT-IR analysis and SEM morphology indicated that the structure of the strain remained integral after biosorption. Amino group plays an important role in the biosorption process, hydroxyl and carboxyl groups are also involved in U binding. (C) 2010 Elsevier B.V. All rights reserved.”
“The magnetic properties, structural properties, and thermal conductivity of FePt films deposited on Ag and
Cu heat sink layers designed for use in heat-assisted magnetic recording (HAMR) were investigated. It has been found that FePt films grown on Cu have a well-defined L1(0)-FePt (001) texture while the FePt films grown on Ag appear to be more isotropic. As the thickness of the heat sink layer increases from 15 to 120 nm the coercivity of the FePt films decreases from 1.7 to 1.5 T for Cu and from 1.3 to 1.0 T for Ag. The thermal conductivity measurements, carried out with the “”laser-flash”" https://www.selleckchem.com/ALK.html technique, revealed that the overall thermal resistance of the examined structures is dominated by the thermal boundary resistance and the interface effects. The increase in the thickness of Ag and Cu heat sink layers does not lead to the higher effective thermal conductivity of the layered structure in the cross-plane direction. The obtained results are important for optimization of the FePt-based structures for HAMR. (C) 2011 American Selleckchem Dactolisib Institute of Physics. [doi:10.1063/1.3564968]“
“In this study, silane crosslinked polypropylene (PP) was
prepared by grafting of silane onto the backbone of PP in a melt process using a twin-screw extruder and then crosslinking in warm water; an attempt was made to improve the melt strength of PP. In the present work, benzoyl peroxide was used as initiator, silane as a monomer, styrene as assisted crosslinking agent. PP foam board with well-distributed and fine blowing hole was prepared by compression molding technology, employing azodicarbamide as blowing agent, talcum powder as nucleation agent. The effects of silane and peroxide concentration on the silane crosslinked PP were investigated. The surface morphology of the foam was accomplished by scanning electron microscopy (SEM). The thermal behavior of the silane crosslinked PP was studied by differential scanning calorimetry (DSC) and the elastic response was investigated by dynamic mechanical analysis (DMA). The melt strength of the silane crosslinked PP was characterized by tension strength at high temperature tests.