Preparation and characterization of cellulose fibers from Meghatyrsus maximus: Applications in its chemical derivatives.

Non-wood lignocellulosic fibers have emerged and are becoming increasingly important as an alternative source of cellulose for derivatives, functional materials, and biofuels. This work aimed, to obtain cellulose from Meghatyrsus maximus grass with adequate properties through an alkaline delignification and alkaline hydrogen peroxide bleaching. Meghatyrsus maximus was chemically characterized as lignocellulosic biomass, which consisted of 45.0 %, cellulose, 35.0 % hemicellulose, and 20.0 % lignin. The obtained cellulose was characterized by Fourier transform infrared spectroscopy, X-ray diffraction analysis, thermogravimetric analysis, and scanning electron microscopy. The alpha-cellulose content was 98.50 % with a crystallinity of 61.0 %. The morphological study by scanning electron microscopy images indicates a clean surface and removal of non-cellulosic components present in the initial raw fibers. These results showed that high-quality cellulose was obtained and is comparable to a commercial alpha-cellulose, highlighting Meghatyrsus maximus as an alternative source of lignocellulosic fibers.

Graphite moderated (252)Cf source.

The Thorium molten-salt reactor is an attractive and affordable nuclear power option for developing countries with insufficient infrastructure and limited technological capability. In the aim of personnel training and experience gathering at the Universidad Simon Bolivar there is in progress a project of developing a subcritical thorium liquid-fuel reactor. The neutron source to run this subcritical reactor is a (252)Cf source and the reactor will use high-purity graphite as moderator. Using the MCNP5 code the neutron spectra of the (252)Cf in the center of the graphite moderator has been estimated along the channel where the liquid thorium salt will be inserted; also the ambient dose equivalent due to the source has been determined around the moderator.

Assessment of state-of-the-art models for predicting the remobilisation of radionuclides following the flooding of heavily contaminated areas: the case of Pripyat River floodplain.

The performances of models are assessed to predict the wash-off of radionuclides from contaminated flooded areas. This process should be accounted for in the proper management of the aftermath of a nuclear accident. The contamination of the Pripyat River water following the inundation of a floodplain heavily contaminated by (90)Sr and (137)Cs of Chernobyl origin is used as the basis for modelling. The available experimental evidence demonstrated that remobilisation of radiostrontium is an important process implying a significant secondary radioactive load of water flowing over the contaminated floodplain. On the contrary, there is no empirical evidence of a similar behaviour for radiocaesium. In general, state-of-the-art models properly predicted the remobilisation of strontium, whereas they significantly overestimated radiocaesium concentrations in water. The necessary model improvements for a more accurate prediction of radiocaesium contamination levels include a reassessment of the values of the model parameters controlling the remobilisation process.