Sintesi di PNA a libertà conformazionale ridotta

The present work started a research project aimed at the synthesis of conformationally “locked” PNA (Peptide Nucleic Acids) monomers. Compared to classic aeg-PNA, this structural modification would result in an improvement in the pairing properties with natural nucleic acids, due to entropic variations in the process. Specifically, an attempt was made to build a PNA monomer around a β-lactam ring. That ring could be imagined as obtained by linking the methylene groups in α position of both the nucleobase and the carboxyl function. These structural properties would imply pre-organization of the final oligomer, improving the pairing process in biological systems. The first step of this work was the investigation of the Staudinger reaction for the ciclization of the lactam ring, and in particular the activation method of the carboxylic group of the nucleobase derivatives. Use of triazine chloride led to the synthesis of the adenine-based β-lactam-PNA. Attempts to synthesize the same monomer based on cytosine, guanine and thymine were unsuccessful, so alternative methods for carboxylic group activation were investigated. Conversion of carboxylic acids to acyl chlorides led to a partial result: despite the method worked well with analogues of the final reactants, it didn’t worked with substrates needed for lactam based PNAs. Search for a valid activation process continued involving carbonyl diimidazole, Mukayama reagent, and LDA (with methylester derivative of nucelobase) without good results. Last, it was investigated a different synthetic approach by first synthesizing a proper backbone with a chlorine in the β- lactam ring. This chlorine ring should undergo substitution by a nucleobase anion to give the desired PNA monomer. Unluckily also this synthetic route didn’t lead to the desired monomers.

Elettrodeposizione di catalizzatori a base di Rh su schiume e fibre metalliche di FeCrAlloy per la produzione di syngas

The preparation of structured catalysts active in the catalytic partial oxidation of methane to syngas, was performed by electrosynthesis of hydroxides on FeCrAlloy foams and fibers. Rh/Mg/Al hydrotalcite-type compounds were prepared by co-precipitation of metallic cations on the support and successive calcination. Electrochemical reactions have been studied during the electrodeposition by linear sweep voltammetry. The experiments were performed at supports immersed in KNO3, KCl, Mg2+ and Al3+ aqueous solutions, starting by different precursors (nitrate and chlorides salts) and modifying the Mg/A ratio. Rh/Mg/Al hydrotalcite-type compounds were deposited on metal foams by applying a -1.2V vs SCE potential for 2000s with a nitrate solution of 0.06M total metal concentration. Firstly it was studied the effect of Mg on the coating propierties, modifying the Rh/Mg/Al atomic ratio (5/70/25, 5/50/45, 5/25/70 e 5/0/95). Then the effect of the amount of Rh was later investigated in the sample with the largest Mg content (Rh/Mg/Al = 5/70/25 and 2/70/28).The results showed that magnesium allowed obtaining the most homogeneous and well adherent coatings, wherein rhodium was well dispersed. The sample with the Rh/Mg /Al ratio equal to5/70/25 showed the best catalytic performances. Decreasing the Rh content, the properties of the coating were not modified, but the catalytic activity was lower, due to a not enough number of active sites to convert the methane. The work on metal fibers focused on the effect of precursor concentration, keeping constant composition, potential and synthesis time at the values of Rh/Mg/Al =5/70/25, -1.2V vs SCE and 1000s. However fibers geometry did not allow to obtain a high quality coating, even if results were quite promising.