New Polyazine-Bridged Ru(II),Rh(III) and Ru(II),Rh(I) Supramolecular Photocatalysts for Water Reduction to Hydrogen Applicable for Solar Energy Conversion and Mechanistic Investigation of the Photocatalytic Cycle

Zhou, Rongwei

09 November 2014

The goal of this research is to test the design constraints of active dpp-bridged RuII,RhIII (dpp = 2,3-bis(2-pyridyl)pyrazine)) supramolecular photocatalysts for water reduction to H2 and provide mechanistic insights into the catalytic cycle. Two member of a new RuII,RhIII motifs with only one Rh-'Cl bond, [(bpy)2Ru(dpp)RhCl(tpy)](PF6)4 ( bpy = 2,2'-bipyridine, tpy = 2,2':6,2"-terpyridine) and [(bpy)2Ru(dpp)RhCl(tpm)](PF6)4, (tpm = tris(1-pyrazolyl)methane), and a cis-RhCl2 model system, [(bpy)2Ru(dpp)RhCl2(bpy)](PF6)3, were prepared. This new motif was to test whether two Rh-'Cl bonds on RhIII are required for the photocatalytic water reduction. 1H NMR spectroscopic analysis of complexes prepared using deuterated ligands was used to characterize these three RuII,RhIII supramolecular complexes. Electrochemical studies suggested that replacing bpy with a tridentate ligand on RhIII shifts the RhIII/II and RhII/I reduction couples positively, which can modulate the orbital energetics of the RhIII LUMO (lowest-unoccupied molecular orbital). This substitute also changes the rate of ligand dissociation following the reduction of RhIII. In tpm and bpy systems, RhII intermediate is more stable than that in the tpy system. All three complexes were good light absorbers in the visible region and weak emitters from their emissive Ru(dπ)-'dpp(π*) 3MLCT (metal-to-ligand charge transfer) excited states at room temperature. The population of a low-lying 3MMCT (metal-to-metal charge transfer) ES (excited state) from the 3MLCT ES contributed to the weak emission, indicating an important intramolecular electron transfer process from dpp' to RhIII upon photoexcitation. The lower-lying 3MMCT excited state in the tpm and tpy systems relative to the bpy system result in a higher rate constant (ket = 2.6 x 10^7 vs 1.7 x 10^7 s-1) for intramolecular electron transfer. Spectrophotochemical analysis suggested that all three complexes were photoinitiated electron collectors capable of collecting two electrons on the RhIII center to generate the RuII,RhI species in the presence of DMA (N,N-dimethylaniline). The observed H2 production from water using [(bpy)2Ru(dpp)RhCl(tpm)](PF6)4 and [(bpy)2Ru(dpp)RhCl(tpy)](PF6)4 established that two halides on RhIII are not necessary in the dpp-bridge RuII,RhIII supramolecular photocatalytic-water-reduction system. This new discovery opens a new approach to the design of different RuII,RhIII motifs for photocatalysis. The active species for water reduction is proposed to be [(bpy)2Ru(dpp)RhICl(TL)]3+ from [(bpy)2Ru(dpp)RhCl(TL)](PF6)4 (TL (terminal ligand) = tpy or tpm) and [(bpy)2Ru(dpp)Rh(bpy)]3+ from [(bpy)2Ru(dpp)RhCl2(bpy)](PF6)3 respectively. Included here is the design and study of a RuII,RhI complex, [(bpy)2Ru(dpp)RhCl(COD)](PF6)3 (COD =1,5-cyclooctadiene) to provide more insights into the photophysical and photochemical properties of polypyridyl RuII,RhI species. Electrochemical and photophysical studies revealed a dpp-based LUMO in this RuII,RhI complex, suggesting dpp reduction upon photoexcitation. Photochemical study found that [(bpy)2Ru(dpp)RhCl(COD)](PF6)3 is an active photocatalyst for water reduction and that additional reduction(s) is (are) required after the generation of the RuII,RhI active species in the RuII,RhIII supramolecular photocatalytic H2 production system. This hypothesis was supported by the electrocatalytic behaviors of the RuII,RhIII supramolecular complexes for proton reduction. Cyclic voltammetry results in the presence of an acid suggested that the protonolysis of the RuII,RhIIH and RuII,RhIH species are electrocatalytic H2-evolution pathways. The mechanism is acid-dependent and influenced by terminal ligand. The studies of electrocatalytic proton reduction on these RuII,RhIII complexes suggested several possible intermediates involved in the photocatalytic water reduction cycle. The insights gained from this research can provide guidance in designing new type of RuII,RhIII and RuII,RhI complexes with better photocatalytic and/or electrocatalytic H2 production performance. / Ph. D.

supramolecular complexes

solar energy

water splitting

hydrogen production

tridentate ligand

rate constant

halide loss

photoinitiated electron collector

excited state quenching

photocatalysis

electrocatalysis

protonation

protonolysis

rhod

Transition-metal-based composite and hybrid nanomaterials for catalytic applications

Zhang, Rui

12 June 2018

In der Entwicklung von Technologien für die nachhaltige Erzeugung, Speicherung und Umwandlung von Energie werden Hochleistungskatalysatoren benötigt. Im Rahmen dieser Arbeit werden verschiedene Übergangsmetall-basierte Katalysatoren, namentlich TiO2/Kohlenstoff-Komposite, anorganisch-organische Hybridsysteme auf Basis von NiFe Phosphonaten sowie Ni Phosphide, synthetisiert, charakterisiert und hinsichtlich ihrer photo- und elektrokatalytischen Eigenschaften untersucht. Es wird gezeigt, dass die Grenzflächeneigenschaften der TiO2/C-Komposite signifikant durch die Gestaltung des Heizvorgangs während der Synthese beeinflusst werden. Insbesondere der Einsatz von Mikrowellenstrahlung vermag die Synthese von Kohlenstoff-basierten Materialien positiv zu beeinflussen. Schnelles Erwärmen führt zu stärkeren Wechselwirkungen zwischen Nanopartikeln und Kohlenstoff, einheitlicheren Beschichtungen und kleineren Partikeln mit schmaleren Partikelgrößenverteilungen, wodurch die photokatalytische Aktivität verbessert wird. Schichtartige, hybride NiFe-Phenylphosphonat-Materialien werden ausgehend in Benzylalkohol dargestellt und ihre Aktivität in der OER im basischen Milieu untersucht. Die Hybridpartikel werden in-situ in NiFe-Hydroxid Nanoschichten umgewandelt. Röntgenspektroskopische Untersuchungen deuten auf eine induzierte, teilweise verzerrte Koordinationsumgebung der Metallzentren im Katalysator hin. Die Kombination der synergistischen Effekte zwischen Ni und Fe mit den strukturellen Eigenschaften des Hybridmaterials ermöglicht einen effizienten Katalysator. Weiterhin werden Nickel-Phosphide durch die thermische Behandlung der Phenyl- oder Methylphosphonate des Nickels, welche Schichtstrukturen aufweisen, in H2(5%)/Ar-Atmosphäre synthetisiert. Ni12P5, Ni12P5-Ni2P und Ni2P Nanopartikel, die mit einer dünnen Schicht aus Kohlenstoffmaterial beschichtet sind, werden erhalten. Ni12P5-Ni2P und Ni2P Nanopartikel katalysieren die Wasserstoffentwicklungsreaktion (HER) im Sauren effektiv. / High-performance catalysts play a key role in the development of technologies for sustainable production, storage, and conversion of energy. In this thesis, transition-metal-based catalysts, including TiO2/carbon composites, hybrid organic-inorganic NiFe phosphonates, and Ni phosphides are synthesized, characterized, and investigated in photocatalytic or electrocatalytic reactions. TiO2 is frequently combined with carbon materials, such as reduced graphene oxide (rGO), to produce composites with improved properties. TiO2 is more efficiently stabilized at the surface of rGO than amorphous carbon. Rapid heating of the reaction mixture results in a stronger coupling between the nanoparticles and carbon, more uniform coatings, and smaller particles with narrower size distributions. The more efficient attachment of the oxide leads to better photocatalytic performance. Layered hybrid NiFe-phenylphosphonate compounds are synthesized in benzyl alcohol, and their oxygen evolution reaction (OER) performance in alkaline medium is investigated. The hybrid particles transformed in situ into NiFe hydroxide nanosheets. X-ray absorption spectroscopy measurements suggest the metal sites in the active catalyst inherited partly the distorted coordination. The combination of the synergistic effect between Ni and Fe with the structural properties of the hybrid results in an efficient catalyst that generates a current density of 10 mA cm-2 at an overpotential of 240 mV. Moreover, nickel phosphides are synthesized through thermal treatment under H2(5%)/Ar of layered nickel phenyl- or methylphosphonates that act as single-source precursors. Ni12P5, Ni12P5-Ni2P and Ni2P nanoparticles coated with a thin shell of carbonaceous material are produced. Ni12P5-Ni2P and Ni2P NPs efficiently catalyze the hydrogen evolution reaction (HER) in acidic medium. Co2P and CoP NPs are also synthesized following this method.

TiO2/Kohlenstoff-Komposite

NiFe-Phosphonat

Nickel-Phosphide

Elektrokatalytische Wasserspaltung

TiO2/carbon composites

Ni phosphide

Electrocatalytic water splitting

NiFe phosphonate

522 Techniken, Ausstattung, Materialien

546 Anorganische Chemie

VE 9857

VE 7047

ddc:522

ddc:546

Développement de nanoparticules de ruthénium comme modèles de catalyseurs pour le craquage de l'eau : approches expérimentale et théorique / Development of ruthenium nanoparticles as catalyst models for the splitting of water : combination of experimental and theoretical chemistry approaches

Gonzalez Gomez, Roberto

11 April 2019

Cette thèse s'inscrit en amont de la problématique de production d'hydrogène (H2) à partir de l'eau. Les réactions impliquées (oxydation de l'eau, WOR et réaction d'évolution de l'hydrogène, HER) requièrent des catalyseurs tels que des nanoparticules (NPs) métalliques. Cette catalyse peut être photoactivée en associant un photosensibilisateur (PS) aux NPs conduisant à des hybrides PS-NPs. Un tel assemblage peut se faire via des groupements acides carboxyliques. Ce travail de doctorat repose sur la combinaison d'outils expérimentaux et théoriques en vue de développer de nouveaux nanocatalyseurs au ruthénium. Notre contribution a consisté à définir une cartographie précise de la surface de Ru NPs stabilisées par des acides carboxyliques avec des chaînes alkyles de longueur différente comme systèmes modèles de catalyseurs PS-NPs pour la photoproduction d'H2 à partir d'H2O. Parmi les principaux objectifs était visée une meilleure compréhension des relations structure/propriétés à l'échelle nanométrique afin d'expliquer les propriétés de surface des NPs et leur viabilité catalytique. Les RuNPs ont été synthétisées par voie organométallique à partir du complexe [Ru(COD)(COT)] comme source de Ru et des acides carboxyliques (éthanoïque, pentanoïque et octanoïque) comme stabilisants. Cette méthode permet la formation de NPs bien contrôlées, fournissant ainsi des systèmes de choix pour des études comparatives fines. Des populations homogènes de RuNPs de taille 1.1 à 1.7 nm ont été obtenues. L'état de surface des NPs a été sondé par différentes techniques analytiques (IR, RMN et WAXS). L'optimisation du ratio [ligand) / [Ru] a permis de disposer de NPs de tailles similaires, et donc de systèmes comparables quel que soit l'acide carboxylique utilisé. Des calculs DFT ont été effectués en parallèle sur un modèle de NP Ru55, dont certains ont alimenté un modèle thermodynamique permettant de s'approcher des conditions expérimentales de température, de pression et de concentration. Une analyse systématique des propriétés des liaisons, des charges atomiques et des états électroniques (DOS, COHP, MPA) a été réalisée. Les calculs des modes de vibration des modèles à base de Ru55 et des déplacements chimiques RMN de clusters [Ru6] ont corroboré et facilité les attributions spectroscopiques expérimentales. Les données spectroscopiques et des études mécanistiques DFT ont montré que les acides carboxyliques interagissent sur la surface métallique sous forme carboxylate. En bon accord, les titrages expérimentaux et théoriques ont montré l'efficacité de l'approche suivie pour cerner l'influence du ligand et de la longueur de la chaîne alkyle sur les propriétés de RuNPs. L'énergie libre de Gibbs de l'adsorption d'hydrogène, un paramètre de référence pour déterminer la viabilité de matériaux pour la catalyse HER, a été calculée par DFT sur des modèles Ru55. Le meilleur nanocatalyseur doit présenter à la fois une surface métallique moyennement encombrée et un ligand avec une longueur de chaîne alkyle intermédiaire, indiquant ainsi comme système le plus prometteur les RuNPs stabilisées par l'acide pentanoïque. Des études d'échange de ligands à la surface de RuNPs stabilisées par l'acide octanoïque ont été réalisées afin de modéliser l'ancrage du PS par un groupe acide carboxylique et complétées par des études théoriques. Les résultats obtenus ont démontré la potentialité de cette approche. Une originalité de ce travail réside dans la combinaison d'études expérimentales et théoriques menées de front pour mieux comprendre la relation structure/propriétés de RuNPs stabilisées par des acides carboxyliques et leur viabilité catalytique pour la production d'H2 à partir d'H2O. Les données obtenues et des résultats catalytiques préliminaires devraient permettre de concevoir des nanocatalyseurs efficaces. Si l'intérêt d'une telle approche a été démontré sur des RuNPs modèles pour le craquage de l'eau, ce travail ouvre d'autres perspectives en nanocatalyse. / This PhD thesis is an upstream study regarding the production of hydrogen (H2) via the water splitting process. The reactions involved (water oxidation, WOR and hydrogen evolution reactions, HER) require efficient catalysts and nanoparticles (NPs) can act so. Such catalysis can be photoactivated by combining photosensitizers (PS) with the NPs leading to hybrid PS-NPs systems, and effective assembling is able via carboxylic acid groups. This work relies on a combination of experimental and theoretical tools to develop novel ruthenium-based nanocatalysts for the water splitting process. Our contribution aimed at achieving a precise mapping of the surface of ruthenium nanoparticles (RuNPs) stabilized by carboxylic acids with an alkyl chain of different length as model systems for the design of PS-NPs catalysts for H2 photoproduction from water. One of the main aims of this PhD was to bring a better understanding of structure/properties relationship at the nanoscale to explain the surface properties of RuNPs stabilized by carboxylic acids and their catalytic viability. RuNPs were synthesized by the organometallic approach using the [Ru(COD)(COT)] complex as metal source and ethanoic, pentanoic and octanoic acids as stabilizers. This synthesis method allows the formation of well-controlled metal NPs, thus providing nanosystems of choice for fine comparative studies. TEM characterization revealed the formation of homogeneous populations of RuNPs in a size range of 1.1 - 1.7 nm. The surface state of the NPs was probed by complementary analytical techniques like IR, NMR and WAXS, leading to a precise mapping of their surface. Optimization studies of the ligand/[Ru] ratio to get NPs with a similar size allowed to have comparable nanosystems whatever the carboxylic acid used as stabilizer and thus to determine the influence of the alkyl chain length. DFT calculations were performed in parallel according to a thermodynamic model fed with DFT energies. Also, a systematic analysis of the bond properties and of the electronic states (Density of States, Crystal Orbital Hamilton Population, atomic charges) was carried out using a Ru55 NP model. DFT calculations of the vibrational features of model RuNPs and of the chemical shifts of model Ru clusters also allowed to secure the spectroscopic experimental assignations. Spectroscopic data and DFT mechanistic studies evidenced that the carboxylic acids lie on the metal surface as carboxylates, together with hydrogen atoms. The results of experimental and theoretical titrations are in good agreement, thus showing the approach followed to be an efficient step to build a model in order to understand the ligand influence on RuNPs properties. Hydrogen adsorption Gibbs free energy, which is a reference parameter to determine the viability of materials for HER catalysis, has been calculated for optimized RuNP structures. The best nanocatalyst revealed to have both, intermediate crowded metal surface and intermediate alkyl chain length for the capping ligand, indicating the RuNPs stabilized by pentanoic acid as the most promising catalyst. Experiments on ligand exchange at the surface of octanoic acid-stabilized RuNPs were also performed in order to model the PS anchoring onto RuNPs through carboxylic acid groups completed by theoretical studies. Results obtained demonstrated the potentiality of this approach. The originality of this work lies with the combination of experimental and theoretical studies in parallel to achieve a better understanding of structure/properties relationship of RuNPs stabilized by carboxylic acids and their catalytic viability for the water-splitting process. Preliminary catalytic results are encouraging, and the data obtained should now allow to design appropriate nanocatalysts. Finally, the interest of this combined approach has been demonstrated through the study of RuNPs for water splitting, but this work opens new opportunities of research in nanocatalysis.

Ruthénium

Nanoparticules

Chimie organométallique

Chimie de coordination

Titrage DFT

Cartographie de surface

Echange de ligands

Hydrogène

Catalyse

Craquage de l'eau

Ruthenium

Nanoparticles

Organometallic Chemistry

Coordination Chemistry

DFT titration

Surface mapping

Ligand exchange

Hydrogen

Catalysis

Water splitting

Heterojunctions of Zinc Selenide and Zinc Sulfide on Titanium Oxide Nano Particles and Their Photocatalyses

Shih, Tsung-Hsiang

22 December 2006

High quality ammonium oxofluorotitanate discoid crystal is successfully grown on glass with an aqueous solution of ammonium hexafluorotitanate and boric acid at the molar ratio of 0.6. The concentration of hydrofluoric acid is less on the glass substrate surface and enhances the ammonium oxofluorotitanate nucleation growth. The growth rate is much higher than that grown on dioctadecyldimethylammonium. From the examinations of X-ray diffraction and high-resolution transmission electron microscopy, the crystal shows high crystalline quality and uniformity. Each titanium oxide octahedral is linked with fluorine and nitrogen atoms. Therefore, ammonium oxofluorotitanate has high potential to be thermally decomposed into high crystalline fluorine and nitrogen co-doped titanium oxide. A simple process for the preparation of nanocrystalline anatase phase titanium oxide converted from ammonium oxofluorotitanate by thermal treatment was developed. The nanocrystalline anatase phase titanium oxide shows a large bandgap reduction due to the co-doping of high concentrations of fluorine and nitrogen. Due to the excellent nanocrystalline quality and the co-doping of higher concentrations of fluorine and nitrogen at the thermal treatment temperature of 800 OC, it is 1.3 times the photocatalytic activities of P-25 due to the visble region usage of Hg lamp light source. The 11.2 times the visible photocatalytic activities of P-25 using blue light-emitting diode as the light source is obtained from thermal treatment temperature of 600 OC. There is one to one correspondence between carrier lifetime and photocatalytic activity. As a result, a highly reactive and visible-light-driven photocatalysis is achieved. The heterostructure of zinc selenide/titanium oxide and zinc sulfide/titanium oxide were prepared by metal-organic chemical vapor deposition on the above-prepared titanium oxide. The energy bandgap of zinc sulfide is much larger than that of titanium oxide and can act as a window for titanium oxide. It would not hinder titanium oxide absorption and preserve the role of fluorine and nitrogen co-doping. The energy bandgap of zinc selenide is near the maximum intensity of solar spectrum and acts as a sensitizer of titanium oxide. The lifetime of electron and hole pairs of heterostructure are about 240 and 207 nsec, which are longer than 65 nsec of titanium oxide prepared at 800 oC thermal treatment. Their photocatalytic activities are further improved to 2.0 and 1.5 times higher than that of commercial P-25. The photocatalysis of titanium oxide is very sensitive to the surface states. Titanium oxide surface defects can act as trapping sites for photo-induced holes and facilitate the separation of photo-induced carriers. Zinc selenide and zinc sulfide can passivate the surface well. It may say that titanium oxide surface defects removal has a negative impact. The density, height, diameter, PL wavelength and intensity of zinc selenide self-assembled quantum dots grown on zinc sulfide/gallium arsenide with the zinc sulfide thickness from 15 to 160 nm are studied. For a fixed 30 sec zinc selenide self-assembled quantum dots growth, it cannot be formed with the zinc sulfide thickness below 15 nm due to the close lattice match between zinc sulfide and gallium arsenide. The zinc sulfide/gallium arsenide is fully lattice relaxed with the zinc sulfide thickness higher than 130 nm examined by X-ray diffraction. The higher quality and density of zinc selenide self-assembled quantum dots can be obtained on zinc sulfide/gallium arsenide with the zinc sulfide thickness far beyond its critical thickness. The maximum zinc selenide self-assembled quantum dots density of 4.9 x 109 cm-2 with the strongest photoluminescence intensity is obtained at the zinc sulfide/gallium arsenide thickness of 130 nm. Clusters are formed on the surface of zinc selenide/gallium arsenide. The selenium segregation is the main mechanism for the formation of clusters. The dislocations will enhance the selenium segregation. Higher zinc selenide cluster corresponds to higher density of dislocations. The non-spherical cluster is formed from the mergence of the two clusters. High quality zinc oxide rods and zinc hydroxide slices are successfully grown on gallium arsenide with the aqueous solution of zinc nitrate and hexamethylenetetramine. The growth can be controlled by the appropriate nitric acid concentration incorporation in the solution. After thermal annealing, the zinc oxide slices transformed from zinc hydroxide slices can contribute much higher photocatalytic activity to 1.2 times to P-25.

Zinc Oxide

Titanium Oxide

Metal-Organic Chemical Vapor Deposition

Heterojunction

Photocatalysis

Gas Sensor

Dye-Sensitized Solar Cell

Water Splitting

Liquid-Phase Deposition

Nano

Fluorine and nitrogen co-doped

Zinc Selenide

Zinc Sulfide

Quantum Dots

Ανάπτυξη καινοτόμων καταλυτών και αντιδραστήρων για την φωτοκαταλυτική διάσπαση του νερού προς παραγωγή υδρογόνου με χρήση ηλιακής ακτινοβολίας

Πατσούρα, Αλεξία

27 January 2009

Η φωτοκαταλυτική διάσπαση του νερού προς παραγωγή υδρογόνου με χρήση φωτοκαταλύτη διοξειδίου του τιτανίου (TiO2) μελετήθηκε με χρήση τεχνητής ηλιακής ή ορατής ακτινοβολίας Βρέθηκε ότι ο αρχικός ρυθμός της αντίδρασης αυξάνεται σημαντικά με την προσθήκη μικρών ποσοτήτων Pt στην επιφάνεια του ημιαγωγού. Στον καταλύτη αυτό, μελετήθηκε η επίδραση του pH καθώς και της θερμοκρασίας του αιωρήματος στην φωτοκαταλυτική παραγωγή υδρογόνου. Τα αποτελέσματα των πειραμάτων έδειξαν ότι τόσο η αύξηση του pH όσο και η αύξηση της θερμοκρασίας έως τους 800C οδηγούν σε ενίσχυση του ρυθμού παραγωγής. Ο ρυθμός μπορεί να αυξηθεί περαιτέρω και να διατηρηθεί σε υψηλά επίπεδα για μεγάλους χρόνους ακτινοβόλησης, αν στο υδατικό αιώρημα προστεθεί ποσότητα «δότη ηλεκτρονίων» σε κατάλληλη συγκέντρωση. Πρόκειται για οργανικές ενώσεις (χρωστικές, αλκοόλες, σάκχαρα κ.α.) που απαντώνται σε απόβλητα χημικών βιομηχανιών, οι οποίες δρουν σαν «θυσιαζόμενες» ενώσεις. Ο ρόλος τους είναι η γρήγορη απομάκρυνση των φωτοπαραγόμενων οπών (ριζών υδροξυλίου) ή/και του φωτοπαραγόμενου οξυγόνου, κατά έναν μη αντιστρεπτό τρόπο, εμποδίζοντας έτσι την επανασύνδεση ηλεκτρονίου-οπής ή/και την αντίστροφη αντίδραση Ο2-Η2 Όταν επιτυγχάνεται πλήρης οξείδωση της οργανικής ένωσης (και των ενδιαμέσων της αντίδρασης) σε διοξείδιο του άνθρακα, το οξυγόνο δεν μπορεί πλέον να απομακρυνθεί από την επιφάνεια του φωτοκαταλύτη, με αποτέλεσμα ο ρυθμός παραγωγής Η2 να μειώνεται στα επίπεδα του ρυθμού μόνιμης κατάστασης, που επιτυγχάνεται απουσία «θυσιαζόμενης» ένωσης από το διάλυμα. Οι συνολικά παραγόμενες ποσότητες Η2 και CO2 είναι ευθέως ανάλογες με την ποσότητα του δότη ηλεκτρονίων που αρχικά προτίθεται στο διάλυμα. Επομένως, η παραγωγή υδρογόνου από την φωτοκαταλυτική διάσπαση του νερού με χρήση «θυσιαζόμενων» ενώσεων αποτελεί μια πολλά υποσχόμενη διεργασία καθώς, παράλληλα με τη δυνατότητα παραγωγής υδρογόνου μέσω της ηλιακής ακτινοβολίας, μπορεί να χρησιμοποιηθεί για την ταυτόχρονη αποικοδόμηση οργανικών ρύπων που απαντώνται σε υγρά βιομηχανικά απόβλητα. / The production of hydrogen from aqueous TiO2 suspensions illuminated with UV/vis or visible light has been examined It has been found that deposition of Pt (0.5 wt.%) on the semiconductor surface results in an increase of the H2 production rate, which goes through a maximum with time of irradiation and then drops to steady-state values comparable to those obtained over bare TiO2. Both, maximum and steady-state rates obtained over Pt/TiO2 suspensions were found to increase with increasing solution pH and temperature. Addition of small quantities of electron donors (such as dyes, alcohols and sugars) in solution results in significantly enhanced rates of H2 production. Results are explained by considering that organic compounds act as sacrificial agents, which become progressively oxidized toward CO2 by consuming photogenerated holes and/or oxygen. This results in decreased rates of electron-hole recombination and oxygen-hydrogen back reaction and, concomitantly, in increased H2-production rates. The rate of photoinduced hydrogen production depends strongly on the concentration of the sacrificial agent employed and to a lesser extent on solution pH and temperature. When complete mineralization of the sacrificial agent is achieved, photogenerated oxygen can no longer be removed from the photocatalyst surface and the H2-production rate drops to steady-state values, comparable to those obtained in the absence of the organic compound in solution. The amounts of carbon dioxide and “additional” hydrogen produced depend on the nature of the organic additive and are directly proportional to its initial concentration in solution. Quantification of results shows that the overall process may be described as “photoinduced reforming of organic compounds at room temperature”. It is concluded that mineralization of organic pollutants, which are common waste products of biomass processing industries, can be achieved with simultaneous production of H2 fuel. The process may provide an efficient and cost effective method for cleaning up waste streams.

Φωτοκατάλυση

Διάσπαση νερού

Παραγωγή υδρογόνου

Ηλιακή ακτινοβολία

Θυσιαζόμενες ενώσεις

628.166

Photocatalysis

Water splitting

Hydrogen production

Titanium dioxide

Solar irradiation

Crificial agents

Degradation of organic pollutants

Modification de nanotubes de TiO2 pour la production d’hydrogène par photodissociation de l’eau sous lumière solaire / Modification of TiO2 nanotubes for hydrogen production by water-splitting under solar light

Gross, Pierre-Alexandre

21 November 2014

Ce travail de thèse traite de la production d’hydrogène par le procédé de photoélectrocatalyse en utilisant une photoanode à base de nanotubes de TiO2 verticalement alignés. L’utilisation du TiO2 étant limité pour des applications solaires en raison de son large gap, il est nécessaire de le modifier. Deux approches sont proposées pour modifier les nanotubes de TiO2 et leur permettre d’absorber la lumière visible. La première est une modification chimique du TiO2 par co-dopage cationique-anionique (Ta-N) ou (Nb-N). Les cations sont insérés durant la croissance des nanotubes grâce à une approche inédite, et l’azote est inséré durant le traitement thermique. Ceci a pour effet la formation d’orbitales hybrides qui entraîne une réduction du gap et une activité sous lumière visible, tout en permettant une stabilité de la structure. La seconde approche consiste à déposer des nanoparticules d’Ag sur la surface des nanotubes de TiO2. Grâce au contrôle de la morphologie des nanoparticules d’Ag, leur résonnance plasmonique permet de stimuler l’absorption du TiO2 et ainsi d’augmenter son rendement à la fois sous lumière UV et sous lumière visible. / This work is about the production of hydrogen by photoelectrocatalysis using a vertically aligned TiO2 nanotubes based photoanode. Utilization of TiO2 for solar applications is limited due to its large band gap, it has to be modified. Two approaches are proposed for the modification of the TiO2 nanotubes to make them absorb visible light. The first one is the chemical modification of the TiO2 by (Ta-N) or (Nb-N) cationic-anionic co-doping. Cations are inserted during the growth of the nanotubes by a novel approach, and nitrogen is inserted during heat treatment. This leads to the formation of hybrid orbitals resulting in a band gap reduction and of activity under visible light. The second approach consists of the deposition of Ag nanoparticles on the surface of the TiO2 nanotubes. Thanks to the control of the morphology of the Ag nanoparticles, their plasmonic resonance can enhance the absorption of TiO2 and thus increase its activity both under UV and visible light.

Photoélectrocatalyse

Photodissociation de l’eau

Hydrogène

Nanotubes de TiO2

Anodisation électrochimique

Co-dopage

Synthèse polyol

Nanoparticules d’Ag

Plasmons de surface

Photoelectrocatalysis

Water-splitting, hydrogen

TiO2 nanotubes

Electrochemical anodization

Co-doping

Polyol synthesis

Ag nanoparticles

Surface plasmons

541.3

Propiedades optoelectrónicas en perovskitas halogenadas y su aplicación en energía y sensores

García Aboal, Rocío

22 October 2021

Tesis por compendio / [ES] La creciente urbanización e industrialización de las sociedades en las últimas décadas han provocado una alta demanda de energía. No obstante, mientras no se desarrollen fuentes de energía renovables que se constituyan como un reemplazo plausible de las actuales, la liberación de gases de efecto invernadero y sus consecuencias sobre el cambio climático difícilmente serán atajadas. Por ello, se está llevando a cabo una intensa búsqueda de energías renovables para un futuro inmediato. En los últimos años, la perovskita ha alcanzado una gran popularidad, centrando numerosos esfuerzos de investigación debido a sus propiedades ópticas y eléctricas únicas. Como por ejemplo su alto coeficiente de absorción y su alta movilidad de carga. Esta tesis comprende seis artículos científicos en torno a las perovskitas. Por un lado, 3 trabajos estudian los fenómenos ópticos que ocurren en el seno del material, con la finalidad de lograr una mejor comprensión de éstos. Puesto que el conocimiento de estos fenómenos ópticos a nivel individual (cristales aislados) permite modular y adaptar su síntesis y morfología para aplicaciones determinadas. Por otro lado, las perovskitas han sido implementadas en distintos dispositivos para su aplicación en tres campos: fotocatálisis, sensores y fotovoltaica. Por primera vez, se ha logrado utilizar este material para la obtención de hidrógeno llevando a cabo la reacción en fase vapor. Asimismo, diversas composiciones de perovskita se han usado para decorar grafeno y detectar niveles traza de Compuestos Orgánicos Volátiles (COV) como benceno y tolueno. Y finalmente se ha desarrollado una estrategia para insertar en la estructura de la perovskita moléculas orgánicas, de forma que se permite una ampliación de la fotorespuesta en el espectro visible. Por lo tanto, las perovskitas se han implementado exitosamente en aplicaciones de diversa índole, constituyéndose como un material prometedor y fácilmente adaptable a los distintos requisitos de cada campo de estudio. / [CAT] La creixent urbanització i industrialització de les societats durant les últimes dècades han provocat una alta demanda d'energia. No obstant això, fins que no es desenvolupen fonts d'energia renovables que puguen ser un reemplaçament plausible de les actuals, l'alliberament de gasos d'efecte hivernacle i les seues conseqüències sobre el canvi climàtic seran difícilment aturades. Per tant, s'està duent a terme una intensa cerca d'energies renovables per a un futur immediat. En els últims anys, la perovskita ha aconseguit una gran popularitat, centrant nombrosos esforços de recerca a causa de les seues propietats òptiques i elèctriques úniques. Per exemple, el seu al coeficient d'absorció i la seua alta mobilitat de càrrega. Aquesta tesi reuneix sis articles científics al voltant de les perovskites. Per una banda, 3 treballs estudien els fenòmens òptics que ocorren en el material, amb la finalitat d'assolir una major comprensió d'aquests. Donat que el coneixement d'aquests fenòmens òptics a nivell individual (cristalls aïllats) permeten modular i adaptar la seua síntesi i morfologia per a determinades aplicacions. Per altra banda, les perovskites han sigut implementats en diferents dispositius per a la seua aplicació en tres camps: fotocatàlisi, sensors i fotovoltaica. Per primera vegada, s'hi ha aconseguit utilitzar aquest material per a l'obtenció d'hidrogen duent a terme la reacció en fase vapor. Així mateix, diverses composicions de perovskita s'han utilitzat per a decorar grafè i detectar nivells traça de Compostos Orgànics Volàtils (COV) com benzè i toluè. I finalment s'ha desenvolupat una estratègia per a inserir en l'estructura de la perovskita molècules orgàniques, de forma que es permet una ampliació de la fotoresposta en l'espectre del visible. Per tant, les perovskites s'han implementat exitosament en aplicacions de diversa índole, constituint-se com un material prometedor i fàcilment adaptable als diferents requisits de cada camp d'estudi. / [EN] During the last decades, the growing urbanization and industrialization result in a significant need for energy. However, since feasible renewable energy sources should be further developed to replace the current energy source, the release of greenhouse gases and their climate change consequences are difficult to overcome. For that reason, the development of renewable energy sources has been attracting growing research efforts. Recently, perovskites gathered great interest owing to their outstanding optical and electrical properties. For instance, their high absorption coefficient and superior charge mobility. This thesis comprises six scientific articles about perovskites. On one hand, 3 works study the optical phenomena that occur within the material in order to achieve a better understanding. The deep knowledge of these optical phenomena's at the individual level (isolated crystals) enable the modulation and tuning of their synthesis and morphology to match specific applications. On another hand, perovskites have been implemented in several devices for their application in three research fields: photocatalysis, sensors, and photovoltaic. For the first time, this nanomaterial was successfully employed for obtaining hydrogen carrying out the reaction in the vapor phase. Likewise, several perovskite compositions have been used for decorating graphene and detect trace levels of Volatile Organic Compounds (VOC) as benzene and toluene. And finally, it has been developed a strategy to insert organic molecules in the perovskite structure, resulting in an enhanced photoresponse in the visible range. Therefore, perovskites have been successfully implemented in several applications, becoming a promising material and easily adaptable to the different requirements needed in each field of study. / Financial support from the Spanish Ministry of Economy and Competitiveness (Severo Ochoa, SEV-2016-0683), Intramural CSIC project 201680I006, and Fundación Ramón Areces (XVII Concurso Nacional para la adjudicación de Ayudas a la Investigación en Ciencias de la Vida y de la Materia) is gratefully acknowledged. This research was financially supported by the Spanish Ministry of Economy and Competitiveness (Mineco) of Spain (TQ2011-26455)2, MAT2015-69669-P, and regional government grant PrometeoII/2017/026. This work was supported by Spanish ministry of Economy, Industry and Competitiveness (MINECO) through the projects TEC2015-74405-JIN, MAT2015-69669-P as well as the regional projects of both Provincia Autonoma di Trento (PAT) of Italy, through the call Grandi Progetti 2012: SIQURO and the Comunidad Valenciana of Spain project PrometeoII/2014/026. This work was supported in part by MICINN and FEDER via grants no. RTI2018-101580- B-I00, by AGAUR under grant. 2017SGR418. S. R.-B. thanks the Research Executive Agency (REA) and the European Commission for the funding received under the Marie Skłodowska Curie actions (H2020-MSCA-IF-2015/Grant agreement number 709023/ZESMO). R. G. A. acknowledges the FPI scholarship from MINECO MAT2015-69669-P. P. A. acknowledges the financial support from the Spanish Government through ‘Severo Ochoa” (SEV-2016-0683, MINECO) and PGC2018-099744-B-I00 (MCIU/AEI/FEDER) / García Aboal, R. (2021). Propiedades optoelectrónicas en perovskitas halogenadas y su aplicación en energía y sensores [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/175357 / TESIS / Compendio

Cavidad óptica

Perovskita

Sensores

Células solares

Monocristales

Fotocatalizador

División de aguas

Guía de ondas

Combustibles solares

Optoelectrónica

Sensors

Perovskite

Optical Cavity

Solar Cell

Single Crystal

Photocatalyst

Water Splitting

Waveguide

Solar Fuels

Optoelectronics

QUIMICA ORGANICA

Fotokatalytický rozklad vody oxidovými polovodiči modifikovanými grafenem/grafenoxidem / Photocatalytic water splitting by oxide semiconductors modified with graphen/graphenoxide

Marek, Jiří

January 2015

This master thesis deals with the topic of alternative production of hydrogen as the energy carrier of the future. The primary focus is on the production of hydrogen based on photocatalytical water splitting in the presence of semiconductor materials (especially modified and unmodified TiO2). The aim of the thesis is a synthesis of nanostructured oxide, graphene/graphene oxide particles and its composites, and a study of its structures and photocatalytical properties regarding photolysis of water. Products of the syntheses are described from the point of view of phase composition, surface area and photocatalytical activity. The main output of the thesis is a discussion of the influence of alkaline complex forming reagents on the hydrothermal low-temperature synthesis of biphasic TiO2, and a study of the influence of graphene/graphene oxide modification on photocatalytical activity of biphasic TiO2.

Preparación y propiedades fotofísicas de materiales grafénicos y puntos cuánticos basados en carbono. Aplicaciones en nanotecnología

García Baldoví, Hermenegildo

01 September 2016

[EN] In this Doctoral Thesis, it has been studied the photophysical and photochemical properties of new nanomaterials based on carbon as graphene derivatives (GO, rGO, graphene (N,O)-codoped and graphene reconstituted halogenated) and two different types of carbon nanoparticles (C-dots and C-NOR). These materials have been applied in the photocatalytic hydrogen generation, such as gas sensors and bioimaging techniques. In a first stage the material was characterized with different spectroscopic and microscopic techniques, and subsequently was studied the behavior of these materials as semiconductors. Using the techniques of fluorescence spectroscopy and absorbance transition has been proven generation state of charge separation after excitation. The different strategies used in the modification of graphene are aimed at getting systems with higher lifetimes of charge separation to harness the energy absorbed from light. It has been observed that the lifetime and quantum yield of charge separation is greater in rGO than GO. For graphenes (N,O)-codoped, which were prepared by pyrolysis natural chitosan, has shown that there is a direct relationship between the percentage of dopants and the energy of the conduction band and the quantum yield of charge separation state. In the case of reconstituted graphenes halogenated it has been shown the influence of the nature of the halogen in the generation charge separation. The charge separation lifetime obtained in these materials is in the scale of microseconds which is encouraging for possible application in photocatalysis and optoelectronic devices. For this reason we use these materials as photocatalysts for hydrogen generating from a methanol-water mixture and yields were higher for the sample (Cl)G that were seven times higher than the starting GO. Nanoparticles have been prepared using two different carbon methodologies. In one case they have been used zeolites with different pore size as templates, being those of small pore size with a directing agents with large structure, such as ITQ-29 and ITQ-12, were the most suitable for production of photoluminescent carbon dots. Pyrolysis of structure directing agent of these zeolites results in carbon quantum dots with particle sizes between 5 and 12 nm and photoluminescence quantum yield of 0.4 to that were used as photoluminescent oxygen sensors. Another methodology involves the synthesis of carbon nanomaterials from annealing of a mixture of PTCA and PEG under air atmosphere. Nanoobjects are obtained with height of 2.5 nm and with an average size of 40 nm. The morphology of the C-NOR is similar to an onion formed by concentric circles. These nanoparticles can be internalized in the human carcinoma HeLa cells and Hep 3B and they have interesting photoluminescent properties, in the same way as in solution. They showed a remarkable biocompatibility affecting in a very low way to cell viability to short periods of exposure according to the test MTT. In order to address the possible use of this nanoparticles in bioimaging a complete toxicology study was performed in vitro. It was performed feasibility assessments, proliferation, apoptosis studies generation and oxidative stress experiments after continuous and limited exposure, and also varying concentrations. It was observed that both nanoparticles showed no toxicity in the two situations at low and higher concentration, although some toxicity was determined at higher concentrations under continuous exposure. These results support the potential use of nanoparticles C-NOR and C-NOR(Eu) as bioimaging agents. / [ES] En esta Tesis Doctoral se han estudiado las propiedades fotofísicas y fotoquímicas de nuevos nanomateriales basados en carbono como son los derivados de grafeno (GO, rGO, grafenos (N,O) codopados y grafenos reconstituidos halogenados) y dos tipos diferentes de nanopartículas de carbono (C-dots y C-NOR). Estos materiales se han aplicado en la generación fotocatalítica de hidrógeno, como sensores de gases y en técnicas de bioimagen. En una primera etapa se ha caracterizado el material con distintas técnicas espectroscópicas y de microscopia, y a posteriori se ha estudiado el comportamiento de estos materiales como semiconductores. Mediante las técnicas de espectroscopia de fluorescencia y de absorbancia de transición se ha comprobado la generación del estado de separación de cargas tras su excitación. Las distintas estrategias utilizadas en la modificación del grafeno van dirigidas a conseguir sistemas con tiempos de vida del estado de separación de cargas elevados que permitan aprovechar la energía absorbida de la luz. Se ha observado que el tiempo de vida y el rendimiento cuántico de la separación de cargas es mayor en el rGO que en el GO. Para los grafenos (N,O)-codopados, que han sido preparados por pirólisis del quitosano natural, se ha demostrado que existe una relación directa entre el porcentaje de dopantes y la energía de la banda de conducción y el rendimiento cuántico de la separación de cargas. Para el caso de los grafenos reconstituidos halógenados se ha demostrado la influencia de la naturaleza del halógeno en la generación del estado de separación de cargas. El tiempo de vida del estado de separación de cargas obtenido en estos materiales se encuentra en la escala de los microsegundos lo cual resulta esperanzador para su posible aplicación en fotocatálisis y en dispositivos optoelectrónicos. Por este motivo utilizamos estos materiales como fotocatalizadores para la generación de hidrógeno a partir de una mezcla metanol agua y los rendimientos más altos fueron para la muestra (Cl) G que fueron siete veces más elevadas que el GO de partida. Se han preparado nanoparticulas de carbono empleando dos metodologías distintas. En un caso se han utilizado zeolitas de distinto tamaño de poro como plantillas, siendo las de tamaño de poro pequeño con agentes directores de estructura voluminosos, como la ITQ-29 y ITQ-12, las más adecuadas para obtener puntos de carbono fotoluminiscentes. La pirólisis del agente director de estructura de estas zeolitas da lugar a puntos cuánticos de carbono con tamaños de partícula entre 5 y 12 nm y un rendimiento de fotoluminiscencia cuántica de 0.4 que fueron utilizados como sensores de oxígeno fluorescentes. La otra metodología consiste la síntesis de nanomateriales de carbono a partir de un recocido de una mezcla de PTCA y PEG bajo atmosfera de aire. Se obtiene nanoobjetos de 2.5 nm de altura y con un tamaño medio de 40 nm. La morfologia de los C-NOR es de círculos concéntricos similar a una cebolla. Estas nanopartículas pueden internalizarse en las células de carcinoma humano HeLa y Hep 3B y presentan propiedades fotoluminiscentes interesantes, de la misma manera que en disolución. Demostraron una notable biocompatibilidad afectando de manera poco perceptible a la viabilidad celular a cortos periodos de exposición según la prueba MTT. Con el fin de abordar el posible uso de esta nanopartículas en bioimagen y su toxicidad se realizó un estudio toxicológico completo in vitro. Se realizaron evaluaciones de viabilidad, proliferación, estudios de generación de apoptosis y estrés oxidativo tras la exposición limitada o continua variando las concentraciones. Se observó que ambas nanopartículas no mostraron toxicidad en las dos situaciones a baja concentración, aunque cierta toxicidad se ha determinado a concentraciones superiores bajo exposición continua. / [CA] En aquesta tesi doctoral s'han estudiat les propietats fotofísiques i fotoquímiques de nous nanomaterials basats en carboni com són els derivats de grafè (GO, rGO, grafens (N,O) codopats i grafenos reconstituïts halogenats) i dos tipus diferents de nanopartícules de carboni ( C-dots i C-NOR). Aquests materials s'han aplicat en la generació fotocatalítica d'hidrogen, com a sensors de gasos i en tècniques de bioimatge. En una primera etapa s'ha caracteritzat el material amb diferents tècniques espectroscòpiques i de microscòpia, i a posteriori s'ha estudiat el comportament d'aquests materials com semiconductors. Mitjançant les tècniques d'espectroscòpia de UV-Vis i d'absorbància de transició (T.A.S.) s'ha comprovat la generació de l'estat de separació de càrregues després de la seva excitació. Les diferents estratègies utilitzades en la modificació del grafè van dirigides a aconseguir sistemes amb temps de vida de l'estat de separació de càrregues elevats que permetin aprofitar l'energia absorbida de la llum. S'ha observat que el temps de vida i el rendiment quàntic de la separació de càrregues és més gran en el rGO que al GO. Per als grafenos (N,O)-codopats, que han estat preparats per piròlisi del quitosan natural, s'ha demostrat que existeix una relació directa entre el percentatge de dopants i l'energia de la banda de conducció i el rendiment quàntic de la separació de càrregues. Per al cas dels grafens reconstituïts halogenats s'ha demostrat la influència de la naturalesa de l'halogen en la generació de l'estat de separació de càrregues. El temps de vida de l'estat de separació de càrregues obtingut en aquests materials es troba en l'escala dels microsegons la qual cosa resulta esperançador per a la seva possible aplicació en fotocatàlisi i en dispositius optoelectrònics. Per aquest motiu utilitzares aquests materials com fotocatalitzadors per a la generació de hidrogen a partir de una mescla metanol- aigua y els rendiments mes alts van ser per la mostra (Cl)G que van ser set vegades mes elevades que el GO de partida. S'han preparat nanoparticules de carboni emprant dues metodologies diferents. En un cas s'han utilitzat zeolites de diferent grandària de porus com plantilles, sent les de mida de porus petit amb agents directors d'estructura voluminosos, com la ITQ-29 i ITQ-12, les més adequades per obtenir punts de carboni fotoluminiscents. La piròlisi de l'agent director d'estructura d'aquestes zeolites dóna lloc a punts quàntics de carboni amb mides de partícula entre 5 i 12 nm i un rendiment de fotoluminiscència quàntica de 0.4 que van ser emprats com a sensors d'oxigen fluorescents. L'altra metodologia consisteix en la síntesi de nanomaterials de carbono a partir d'un recuit d'una barreja de PTCA i PEG sota atmosfera d'aire. S'obté nanoobjectes de 2.5 nm d'alçada i amb una longitud mitjana de 40 nm. La morfologia dels C-NOR és de cercles concèntrics similar a una ceba. Aquestes nanopartícules poden internalitzar-se en les cèl·lules de carcinoma humà HeLa i Hep 3B i presenten propietats fotoluminiscents interessants, de la mateixa manera que en dissolució. Van demostrar una notable biocompatibilitat afectant de manera poc perceptible a la viabilitat cel·lular a curts períodes d'exposició segons la prova MTT. Per tal d'abordar el possible ús d'aquesta nanopartícules en bioimatge i la seva toxicitat es va realitzar un estudi toxicològic complet in vitro. Es van realitzar avaluacions de viabilitat, proliferació, estudis de generació d'apoptosi i estrès oxidatiu després de l'exposició limitada o contínua amb diferents concentracions. Es va observar que les dos nanopartícules no van mostrar toxicitat en les dues situacions a baixa concentració, encara que certa toxicitat s'ha determinat a concentracions superiors sota exposició contínua. Aquests resultats donen suport a la possible utilització de nanopartícules C-NOR i C-NOR(Eu) com a agents / García Baldoví, H. (2016). Preparación y propiedades fotofísicas de materiales grafénicos y puntos cuánticos basados en carbono. Aplicaciones en nanotecnología [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/68505 / TESIS / Premios Extraordinarios de tesis doctorales

Nanoparticulas

Grafeno

Puntos cuanticos de carbono

C-dots

Nanocebollas de carbono

C-NOR

Water splitting

Grafenos halogenados

Grafenos dopados

Dopaje

Carbono

Fotofísica

Quantum dots

Nanoparticles

Carbon nanoparticles

Carbon nano-onion

QUIMICA ORGANICA

[pt] SIMULAÇÃO TERMODINÂMICA E MODELAGEM CINÉTICA DO PROCESSO DE DECOMPOSIÇÃO DE SULFATOS COM DIFERENTES NÍVEIS DE ESTABILIDADE TÉRMICA NA PRESENÇA DE CATALISADORES / [en] THERMODYNAMIC SIMULATION AND KINETIC MODELING OF THE DECOMPOSITION PROCESS OF SULFATES WITH DIFFERENT LEVELS OF THERMAL STABILITY IN THE PRESENCE OF CATALYSTS

NATHALLI MEORLLUW MELLO

29 September 2022

[pt] Os ciclos termoquímicos de decomposição de água relacionados ao enxofre são uma importante classe de processos químicos considerados para a produção de hidrogênio. Recentemente, a decomposição térmica do sulfato de magnésio e sulfato de amônio tem sido relatada como uma potencial operação unitária em um desses ciclos. Portanto, algum interesse tem sido observado no uso de catalisadores para diminuir a energia de ativação de sulfatos que se decompõem em altas temperaturas, como o magnésio e a adição de um agente modificador para facilitar a separação dos produtos no caso de sulfatos que se decompõem em baixas temperaturas como amônio. Neste contexto, a presente tese relata os resultados da modelagem termodinâmica e cinética associada a este sistema de reação na presença de Pd suportado sobre gama-Al(2)O(3). Para o sistema Mg a presença de tais espécies é responsável por deslocar a temperatura de decomposição para valores mais baixos em pelo menos 100 graus C. Observou-se que o teor de magnésio ainda está orientado para a formação de MgO. Os resultados obtidos indicam que o catalisador Pd/Al(2)O(3) pode ser uma boa alternativa na redução da temperatura de decomposição térmica, pois sua presença foi responsável por diminuir a energia de ativação do processo de 368,2 para 258,8 kJ.mol(-1). Para o sistema NH4 pode-se observar que ocorre em quatro etapas e a formação de sulfato de alumínio, sendo a última espécie portadora de sulfato, proporciona a separação do óxido de enxofre liberando-o em uma etapa diferente dos demais produtos gasosos. A presença de paládio pode atuar como redutor da energia de ativação desta etapa, deslocando a temperatura de decomposição para valores inferiores em pelo menos 90 graus C e a reduzindo os valores de energia de ativação entre 12 – 30 por cento abaixo do encontrado na literatura oriundos de modelos gráficos. / [en] The sulfur related thermochemical water-splitting cycles are an important class of chemical processes considered for hydrogen production. Recently, the magnesium and the ammonium sulfate thermal decomposition have been reported as a potential unit operation in one of these cycles. Therefore, some interest has been observed in the use of catalysts to lower the activation energy for sulfates that decompose in high temperatures, as such magnesium and the addition of a modifying agent to facilitate separation of the products in the case of sulfates that decompose into low temperatures as ammonium. In this context, the present thesis reports the thermodynamics and kinetics modeling results associated with this reactions systems in the presence of a Pd supported over gamma-Al(2)O(3). For Mg system the presence of such species is responsible for shifting the decomposition temperature to lower values in at least 100 degrees C. It was observed that the magnesium content is still oriented towards MgO formation. The obtained results indicate that the Pd/Al(2)O(3) catalyst could be a good alternative in reducing the thermal decomposition temperature as its presence was responsible for diminishing the process activation energy from 368.2 to 258.8 kJ.mol(-1). For NH(4) system it can be observed four steps for reactions and formation of aluminum sulfate, as the last sulfate bearing species, provided the separation of the sulfur oxide releasing it in a different step from the other gaseous products. The presence of palladium can act as an activation energy reducer, shifting the decomposition temperature to lower values in at least 90 degrees C and decreasing the activation energy by 12 – 30 percent than that found in the literature.

[pt] DECOMPOSICAO TERMICA

[pt] AL2O3

[pt] PD

[pt] CINETICA

[pt] CICLO DE DECOMPOSICAO AGUA-ENXOFRE

[pt] NH4 2 SO4

[pt] MGSO4

[en] THERMAL DECOMPOSITION

[en] AL2O3

[en] PD

[en] KINETICS

[en] SULFUR WATER-SPLITTING CYCLES

[en] NH4 2 SO4

[en] MGSO4