Electro-remediação de solos contaminados com pesticidas

O herbicida bentazona (2,2-dióxido de 3-isopropil (1H) -benzo-2,1,3-triadiazin-4- ona) é um herbicida pós emergente selectivo, com uso recomendado para a cultura do arroz. Apresenta baixa persistência no solo, onde é adsorvido pelos colóides minerais e orgânicos, e um tempo de meia vida inferior a 2 semanas, associado a um elevado potencial de lixiviação e contaminação de águas subterrâneas. Nos estudos efectuados até ao momento, a bentazona não é degradada pelos microrganismos, o que levou à necessidade de procurar outras técnicas de remoção do pesticida. Foi estudada uma técnica inovadora, a electro-remediação, que consiste na aplicação de uma corrente contínua de baixa intensidade à matriz contaminada, funcionando o campo eléctrico formado como “agente de limpeza”. Este campo arrasta os contaminantes pela matriz, por acção de processos de transporte, nomeadamente, electromigração, electroosmose e electroforese. Foram realizados quatro ensaios, num solo colhido num arrozal, onde se procedeu à contaminação forçada do solo com uma solução de bentazona, submetendo-o à acção dum campo eléctrico durante vários dias. Os teores de bentazona no solo, após extracção com solvente por sonicação, e nas soluções de anólito e católito, após extracção por fase sólida, foram determinados por cromatografia líquida de alta eficiência. Concluiu-se que a bentazona é mobilizada no solo pela acção do campo eléctrico e esta remoção é dependente do pH.

Spectroscopic characterization of a novel 2 /[4Fe /4S] ferredoxin isolated from Desulfovibrio desulfuricans ATCC 27774

Inorganica Chimica Acta 356 (2003) 215-221

Development of 2-oxazoline-based hydrogels and porous polyester microparticles in scCO2

Thesis submitted to Faculdade de Ciências e Tecnologia from Universidade Nova de Lisboa in partial fulfillment of the requirements for the obtention of the degree of Master of Science in Biotechnology

Development and application of NMR techniques to study water-in-CO2 microemulsions

Self-assembly is a phenomenon that occurs frequently throughout the universe. In this work, two self-assembling systems were studied: the formation of reverse micelles in isooctane and in supercritical CO2 (scCO2), and the formation of gels in organic solvents. The goal was the physicochemical study of these systems and the development of an NMR methodology to study them. In this work, AOT was used as a model molecule both to comprehensively study a widely researched system water/AOT/isooctane at different water concentrations and to assess its aggregation in supercritical carbon dioxide at different pressures. In order to do so an NMR methodology was devised, in which it was possible to accurately determine hydrodynamic radius of the micelle (in agreement with DLS measurements) using diffusion ordered spectroscopy (DOSY), the micellar stability and its dynamics. This was mostly assessed by 1H NMR relaxation studies, which allowed to determine correlation times and size of correlating water molecules, which are in agreement with the size of the shell that interacts with the micellar layer. The encapsulation of differently-sized carbohydrates was also studied and allowed to understand the dynamics and stability of the aggregates in such conditions. A W/CO2 microemulsion was prepared using AOT and water in scCO2, with ethanol as cosurfactant. The behaviour of the components of the system at different pressures was assessed and it is likely that above 130 bar reverse microemulsions were achieved. The homogeneity of the system was also determined by NMR. The formation of the gel network by two small molecular organogelators in toluene-d8 was studied by DOSY. A methodology using One-shot DOSY to perform the spectra was designed and applied with success. This yielded an understanding about the role of the solvent and gelator in the aggregation process, as an estimation of the time of gelation.