Analisi del ciclo di vita di processi chimici industriali: applicazione alla sintesi di acrilonitrile mediante reazione di ammonossidazione

La green chemistry può essere definita come “l’utilizzo di una serie di principi che riducono o eliminano l’uso o la formazione di sostanze pericolose nella progettazione, produzione e applicazione di prodotti chimici”. . È in questo contesto che si inserisce la metodologia LCA (Life Cycle Assessment), come strumento di analisi e di valutazione. Lo scopo del presente lavoro di tesi è l’analisi degli impatti ambientali associati a processi chimici, ambito ancora poco sviluppato nella letteratura degli studi di LCA. Viene studiato e modellato il ciclo di vita (dall’ottenimento delle materie prime fino alla produzione del prodotto) della reazione di ammonossidazione per la produzione di acrilonitrile, valutando e comparando due alternative di processo: quella tradizionale, che utilizza propilene ( processo SOHIO), e le vie sintetiche che utilizzano propano, ad oggi poco sviluppate industrialmente. Sono stati pertanto creati sei scenari: due da propene (SOHIO FCC, con propene prodotto mediante Fluid Catalytic Cracking, e SOHIO Steam), e quattro da propano (ASAHI, MITSUBISHI, BP povero e ricco in propano). Nonostante la produzione dell’alcano abbia un impatto inferiore rispetto all’olefina, dovuto ai minori stadi di processo, dai risultati emerge che l’ammonossidazione di propano ha un impatto maggiore rispetto a quella del propene. Ciò è dovuto ai processi catalitici che utilizzano propano, che differiscono per composizione e prestazioni, rispetto a quelli da propene: essi risultano meno efficienti rispetto ai tradizionali, comportando maggiori consumi di reattivi in input . Dai risultati emerge che gli scenari da propano presentano maggiori impatti globali di quelli da propene per le categorie Cambiamento climatico, Formazione di materiale e Consumo di combustibili fossili. Invece per la categoria Consumo di metalli un impatto maggiore viene attribuito ai processi che utilizzano propene, per la maggior percentuale di metalli impiegata nel sistema catalitico, rispetto al supporto. L’analisi di contributo, eseguita per valutare quali sono le fasi più impattanti, conferma i risultati. Il maggior contributo per la categoria Consumo di combustibili fossili è ascrivibile ai processi di produzione del propano, dell’ammoniaca e del solfato di ammonio ( legato all’ammoniaca non reagita ). Stessi risultati si hanno per la categoria Cambiamento climatico, mentre per la categoria Formazione di materiale particolato, gli impatti maggiori sono dati dai processi di produzione del solfato di ammonio, del propano e dell’acido solforico (necessario per neutralizzare l’ammoniaca non reagita). Per la categoria Consumo di metalli, il contributo maggiore è dato dalla presenza del catalizzatore. È stata infine eseguita un’analisi di incertezza tramite il metodo Monte Carlo, verificando la riproducibilità dei risultati.

Oxidative properties of the Iron - Thymine-1-acetic acid - Hydrogen peroxide catalytic system

The oxidation of alcohols and olefins is a pivotal reaction in organic synthesis. However, traditional oxidants are toxic and they often release a considerable amounts of by-products. Here, two IronIII-based systems are shown as oxidative catalyst, working in mild conditions with hydrogen peroxide as primary oxidant. An efficient catalytic system for the selective oxidation of several alcohols to their corresponding aldehydes and ketones was developed and characterized, [Fe(phen)2Cl2]NO3 (phen=1,10-Phenantroline). It was demonstrated that the adoption of a buffered aqueous solution is of crucial importance to ensure both considerable activity and selectivity.The Iron - Thymine-1-acetic acid in-situ complex was studied as catalyst in alcohol oxidations and C-H oxidative functionalization, involving hydrogen peroxide as primary oxidant in mild reaction conditions. The catalytic ability in alcohol oxidations was investigated by Density Functional Theory calculations, however the catalyst still has uncertain structure. The system shows satisfactory activity in alcohol oxidation and aliphatic rings functionalization. The Fe-THA system was studied in cyclohexene oxidation and oxidative halogenations. Halide salts such as NBu4X and NH4X were introduced in the catalytic system as halogens source to obtain cyclohexene derivatives such as halohydrins, important synthetic intermediates.The purpose of this dissertation is to contribute in testing new catalytic systems for alcohol oxidations and C-H functionalization. In particular, most of the efforts in this work focus on studying the Iron - Thymine-1-acetic acid (THA) systems as non-heme oxidative model, which present: •an iron metal centre(s) as a coordinative active site, •hydrogen peroxide as a primary oxidant, •THA as an eco-friendly, biocompatible, low cost coordinating ligand.

Synthesis, characterization and catalytic performances of ruthenium-based catalysts for the acceptorless dehydrogenative coupling of butanol

A growing interest towards new sources of energy has led in recent years to the development of a new generation of catalysts for alcohol dehydrogenative coupling (ADC). This green, atom-efficient reaction is capable of turning alcohol derivatives into higher value and chemically more attractive ester molecules, and it finds interesting applications in the transformation of the large variety of products deriving from biomass. In the present work, a new series of ruthenium-PNP pincer complexes are investigated for the transformation of 1-butanol, one of the most challenging substrates for this type of reactions, into butyl butyrate, a short-chain symmetrical ester widely used in flavor industries. Since the reaction kinetics depends on hydrogen diffusion, the study aimed at identifying proper reactor type and right catalyst concentration to avoid mass transfer interferences and to get dependable data. A comparison between catalytic activities and productivities has been made to establish the role of the different ligands bonded both to the PNP binder and to the ruthenium metal center, and hence to find the best catalyst for this type of reaction.

Catalytic decomposition of formic acid using supported metal nanoparticles

Upgrade of hydrogen to valuable fuel is a central topic in modern research due to its high availability and low price. For the difficulties in hydrogen storage, different pathways are still under investigation. A promising way is in the liquid-phase chemical hydrogen storage materials, because they can lead to greener transformation processes with the on line development of hydrogen for fuel cells. The aim of my work was the optimization of catalysts for the decomposition of formic acid made by sol immobilisation method (a typical colloidal method). Formic acid was selected because of the following features: it is a versatile renewable reagent for green synthesis studies. The first aim of my research was the synthesis and optimisation of Pd nanoparticles by sol-immobilisation to achieve better catalytic performances and investigate the effect of particle size, oxidation state, role of stabiliser and nature of the support. Palladium was chosen because it is a well-known active metal for the catalytic decomposition of formic acid. Noble metal nanoparticles of palladium were immobilized on carbon charcoal and on titania. In the second part the catalytic performance of the “homemade” catalyst Pd/C to a commercial Pd/C and the effect of different monometallic and bimetallic systems (AuxPdy) in the catalytic formic acid decomposition was investigated. The training period for the production of this work was carried out at the University of Cardiff (Group of Dr. N. Dimitratos).