Titania Nanoscale Films and Surfaces : Surface Science Investigation of Structure and Properties

Ragazzon, Davide

January 2014

This thesis presents surface science studies, investigating several aspects of titanium dioxide at the atomic scale. The greater part of this work is devoted to the preparation by chemical vapor deposition (CVD) of titanium(IV) tetraisopropoxide (TTIP) of ultrathin TiO2 or TiOx films on Au(111). Four ordered structures were growth and characterized. It was also demonstrated how the morphology of the film (wetting film vs island) can be tailored. The acquired knowledge about the CVD process was exploited to load nano porous gold with titania, enhancing its catalytic activity. The reactivity towards water adsorption of the titania structures on Au(111) was also investigated. Finally, part of this work concerned the studying of the behavior of water on the stoichiometric rutile TiO2(110) surface, combining the experiments with density-functional theory (DFT) calculations and (kinetic) Monte Carlo simulations. The main experimental techniques used in this work are low-energy electron diffraction (LEED), scanning tunneling microscopy (STM) and photoelectron spectroscopy (PES).

Photoelectron spectroscopy

PES

XPS

scanning tunneling microscopy

STM

titania

titanium oxide

TiO2

Au(111)

gold

water

H2O

rutile

Η επίδραση της θερμικής καταπόνησης και του ατμοσφαιρικού αέρα στην ηλεκτρική αγωγιμότητα της πολυπυρρόλης και των νανοσύνθετων πολυπυρρόλης / 5% w/w TiO2

Εμμανουήλ, Κωνσταντίνος

18 February 2010

Σε αυτήν την εργασία μελετήθηκε η συμπεριφορά της ηλεκτρικής ειδικής αγωγιμότητας συνεχούς, δειγμάτων πολυπυρρόλης και νανοσυνθέτων πολυπυρρόλης/5% w/w TiO2, συναρτήσει της θερμοκρασίας. Οι μετρήσεις πραγματοποιήθηκαν τόσο σε μόλις παρασκευασθέντα δείγματα, καθώς και στα ίδια δείγματα μετά από συγκεκριμένη παραμονή τους σε θερμοκρασία καταπόνησης για διαφορετικά χρονικά διαστήματα. Οι θερμοκρασίες καταπόνησης ήταν 100, 300 και 380Κ. Τα χρονικά διαστήματα στα οποία παρέμεναν τα δείγματα στη συγκεκριμένη θερμοκρασία καταπόνησης κάθε φορά, έβαιναν αυξανόμενα από 0 μέχρι 30 ώρες περίπου. Η θερμική καταπόνηση των δειγμάτων γινόταν σε ατμόσφαιρα δωματίου και σε αδρανή ατμόσφαιρα ηλίου. Η επιφάνεια των δειγμάτων μελετήθηκε με μικροφωτογραφίες SEM πριν και μετά την θερμική καταπόνηση. Τόσο για την καθαρή πολυπυρρόλη, όσο και για τα νανοσύνθετα πολυπυρρόλης/5% w/w TiO2 η αγωγιμότητα ακολουθεί την σχέση , η οποία ισχύει για την περίπτωση υλικού με δομή κοκκώδους μετάλλου. Στη δομή αυτή, αγώγιμες νησίδες πολυμερούς κατανέμονται τυχαία μέσα σε μονωτικό υλικό. Η παραπάνω σχέση ισχύει όταν οι μονωτικοί φραγμοί είναι αρκετά στενοί, έτσι ώστε οι φορείς αγωγιμότητας, λόγω φαινομένου σήραγγος, να περνούν από περιοχές μικρής επιφάνειας, εκεί όπου οι κόκκοι πλησιάζουν πολύ μεταξύ τους. Λόγω του μικρού μεγέθους αυτών των περιοχών διέλευσης, η συγκέντρωση των φορέων εκατέρωθεν του μονωτικού φραγμού εμφανίζει έντονες θερμικές διακυμάνσεις συνοδευόμενες από αντίστοιχες διακυμάνσεις της τάσης, οι οποίες τελικά καθορίζουν την διέλευση των φορέων (μοντέλο FIT – Fluctuation Induced Tunneling). Με βάση το μοντέλο FIT υπολογίστηκαν οι χαρακτηριστικές παράμετροι σ0, T1 και T0. Η παράμετρος σ0 αποτελεί μέτρο της αγωγιμότητας στο εσωτερικό των αγώγιμων νησίδων, η T1 εκφράζει το ύψος του φραγμού της δυναμικής ενέργειας, τον οποίο πρέπει να διασχίσει ο φορέας, ενώ το T0 σε συνδυασμό με την παράμετρο T1 επιτρέπουν τον υπολογισμό της απόστασης s μεταξύ των αγώγιμων νησίδων. Η κλίση των καμπύλων είναι μικρότερη (περίπου η μισή) για τα νανοσύνθετα από ότι για τα δείγματα καθαρής πολυπυρρόλης, τόσο σε ατμόσφαιρα δωματίου, όσο και σε αδρανή ατμόσφαιρα He. Αυτό ερμηνεύεται από το γεγονός ότι, η TiO2 έχει μεγαλύτερο ενεργειακό χάσμα (3.2eV) από την πολυπυρρόλη (2.5eV), οπότε η θερμική διέγερση των φορέων είναι πιο δύσκολη στα δείγματα νανοσυνθέτων. Με τη δομή κοκκώδους μετάλλου συμφωνεί και ο νόμος της θερμικής γήρανσης, , από τον οποίο προκύπτει γραμμικότητα της . Από την κλίση των ευθειών προκύπτει ότι η παρουσία της TiO2 επιβραδύνει τη γήρανση μειώνοντας την κινητικότητα των αλυσίδων του πολυμερούς. Από τις μικροφωτογραφίες SEM συνάγεται ότι η δομή, τόσο της πολυπυρρόλης, όσο και του νανοσυνθέτου δεν είναι συμπαγής, αλλά εμφανίζεται σαν ένα συσσωμάτωμα κόκκων με διαστάσεις 200–300nm. Οι διαστάσεις των νανοσωματιδίων της TiO2 προκύπτουν περίπου 20nm, όπως αναμένεται από τις προδιαγραφές της, ενώ οι διαστάσεις των αγώγιμων νησίδων της πολυπυρρόλης εκτιμώνται με βάση τις αντίστοιχες διαστάσεις των αγώγιμων νησίδων στην πολυανιλίνη, της τάξεως των 20-30nm. Το γεγονός ότι οι διαστάσεις των αγώγιμων νησίδων είναι περίπου ίσες με εκείνες των νανοσωματιδίων TiO2 σημαίνει ότι οι δεύτερες μπορούν να παρεμβάλλονται ανάμεσα στις πρώτες, πράγμα που δικαιολογεί τον ρυθμό μεταβολής του φραγμού δυναμικής ενέργειας, ο οποίος είναι μικρότερος στην περίπτωση του νανοσυνθέτου. Μια άλλη πληροφορία από τις μικροφωτογραφίες SEM είναι ότι, η θερμική καταπόνηση εξομαλύνει το ανάγλυφο της επιφάνειας και συντελεί στην συσσωμάτωση των κόκκων του υλικού. Η διαδικασία αυτή συμβαίνει με την απομάκρυνση του Cl- με μορφή HCl, γεγονός το οποίο μειώνει την αγωγιμότητα λόγω αποπρωτονίωσης των αλυσίδων του πολυμερούς. Αντίθετα, η ταυτόχρονη συσσωμάτωση των κόκκων του υλικού αυξάνει την αγωγιμότητα. Παρατηρούμε ότι συνυπάρχουν δύο ανταγωνιζόμενοι μηχανισμοί μεταβολής της ηλεκτρικής αγωγιμότητας. Οι διαφορές στις ισόθερμες καμπύλες για θερμοκρασίες 100, 300 και 380Κ, σε περιβάλλον ατμοσφαιρικού αέρα, αφενός, και αδρανούς ατμόσφαιρας ηλίου αφετέρου, συνδέονται με τον ρόλο που παίζουν οι εξής παράγοντες: a) Η θερμοκρασία, η οποία καθορίζει την κινητικότητα των πολυμερικών αλυσίδων και τη διέγερση των φορέων αγωγιμότητας, καθώς και το ρυθμό διάχυσης και την ταχύτητα των χημικών αντιδράσεων με το οξυγόνο και την υγρασία του αέρα. Θα πρέπει να ληφθεί υπόψη ότι η θερμοκρασία υαλώδους μετάβασης Tg για την PPy, πάνω από την οποία συμβαίνουν συνεργατικές κινήσεις των αλυσίδων, ποικίλει ανάμεσα στους 250 και στους 400Κ και εξαρτάται από τη μέθοδο παρασκευής, τη φύση των προσμίξεων και τη θέση που καταλαμβάνουν μέσα στο υλικό, είτε συμμετέχοντας στη δομή της αλυσίδας, είτε σχηματίζοντας πλευρικούς κλάδους. b) Η ύπαρξη οξυγόνου και υγρασίας του ατμοσφαιρικού αέρα, τα οποία, όπως έχει αναφερθεί παίζουν σημαντικό ρόλο στον τεμαχισμό των αλυσίδων, ο οποίος καταστρέφει το συζυγή χαρακτήρα του υλικού. c) Η ύπαρξη TiO2, η οποία χαρακτηρίζεται από ενεργειακό χάσμα μεγαλύτερο από εκείνο της PPy και σε υψηλές θερμοκρασίες συντελεί στην μεταφορά οξυγόνου στο πολυμερές με αποτέλεσμα ανάλογο με εκείνο που προκαλεί το οξυγόνο του ατμοσφαιρικού αέρα. Ειδικότερα οι καμπύλες στους 100Κ δείχνουν τον καθοριστικό ρόλο του οξυγόνου και της υγρασίας στην μείωση της αγωγιμότητας σε ατμόσφαιρα δωματίου. Επί πλέον σε ατμόσφαιρα He αποκαλύπτουν μηχανισμό αύξησης της αγωγιμότητας. Στους 300Κ η παρουσία TiO2 εξασθενεί τον μηχανισμό βελτίωσης των αλυσίδων, διότι τα νανοσωματίδια μειώνουν την κινητικότητα και επομένως την διευθέτηση των πολυμερικών αλυσίδων και την αύξηση της αγωγιμότητας. Τα μέγιστα που παρατηρούνται στα πρώτα 10min αποδίδονται στη βελτίωση της διάταξης των αλυσίδων του πολυμερούς. Για μεγαλύτερους χρόνους επικρατούν οι καταστροφικοί μηχανισμοί γήρανσης, λόγω της παρουσίας οξυγόνου και υγρασίας, αλλαγές της δομής, οι οποίοι αποκόπτουν τους δρόμους διέλευσης των φορέων, με αποτέλεσμα την μείωση της αγωγιμότητας. Εξαίρεση αποτελεί η πολυπυρρόλη σε ατμόσφαιρα He, όπου η έλλειψη οξυγόνου και υγρασίας έχει σαν αποτέλεσμα τη αύξηση της αγωγιμότητας σε όλη τη διάρκεια της θερμικής καταπόνησης. Εντελώς διαφορετική είναι η συμπεριφορά του νανοσυνθέτου πολυπυρρόλης/5% w/w TiO2 στη θερμοκρασία των 300Κ σε ατμόσφαιρα He. Η μείωση της αγωγιμότητας με την θερμική καταπόνηση μπορεί να αποδοθεί στη μεταφορά οξυγόνου από την TiO2 στο πολυμερές, με αποτέλεσμα τον τεμαχισμό των αλυσίδων και τη μείωση της αγωγιμότητας. Τέλος, στους 380Κ η εμφάνιση του μέγιστου είναι λιγότερο έντονη και δείχνει ότι στη θερμοκρασία αυτή, υπερισχύουν πολύ περισσότερο οι καταστροφικοί μηχανισμοί, τόσο παρουσία ατμοσφαιρικού αέρα, όσο και αδρανούς He. / In this thesis, the DC specific conductivity was studied on polypyrrole (PPy) and polypyrrole/5% w/w TiO2 nanocomposite samples as a function of temperature. The measurements were carried out οn fresh as well as οn samples that had remained at an ageing temperature for specific time periods. The ageing temperatures were 100, 300 and 380K. The time periods for which the samples were aged started from 0 and led up to 30 hrs approximately. The thermal ageing was conducted in room atmosphere as well as in inert He. The surface of the samples was studied with Scanning Electron Microscopy (SEM), before and after thermal treatment. Both for PPy and PPy/5% w/w TiO2 nanocomposites the specific DC conductivity follows the relation , which is valid in the case of materials with a granular metal structure. In this structure, conducting islands of polymer are randomly distributed in an electrically insulating substrate. The above relation is valid when the insulating barriers are narrow enough so that the charge carriers, because of the tunneling effect, can pass through regions of little area, where the grains are close to one another. Because of the small size of these regions, the density of carriers on either side of the insulating barrier exhibits intense thermal fluctuations, which are accompanied by corresponding fluctuations in voltage, which, in effect, determines the passage of carriers (Fluctuation Induced Tunneling model – FIT). Based on the FIT model, the characteristic parameters σ0, T1 and T0 were calculated. The parameter σ0 is a measure of the conductivity inside the conducting islands, T1 expresses the height of the potential energy barrier, which the carrier must overcome, whilst T0 in conjunction with parameter T1, allows the calculation of the distance s between the conducting islands. The slope of the curves is of lower value (about half) for the nanocomposites than for the pure PPy samples, both in room atmosphere measurements, as well as for inert He ones. This can be explained by the fact that TiO2 has a higher band gap (3.2eV) than polypyrrole (2.5eV), thus the thermal excitation is harder for nanocomposite samples. The thermal ageing law is in agreement with the granular metal model, from whom we can derive the linearity of . By the slope of the lines, we derive that the presence of TiO2 slows the ageing by diminishing the mobility of the polymer chains. By SEM microphotographs it is deducted that the structure, of both polypyrrole and the nanocomposites, is not compact, but appears as an aggregate of grains with diameters of 200-300nm. The dimensions of the TiO2 nanoparticles are about 20nm, as we expected by the specifications of the titania used, whilst the dimensions of the conducting islands of polypyrrole are estimated, based on the corresponding structures in conducting polyaniline, in the order of 20-30nm. The fact that the dimensions of the conducting islands are about the same as the size of the TiO2 nanoparticles, means that the latter can intervene between the islands, which can justify the rate of change of the height of the potential energy barrier that is smaller in the case of the nanocomposite. Another piece of information derived from the SEM microphotographs is that the thermal treatment acts to smooth the relief of the surface and contributes to the agglomeration of the material grains. This process happens with the removal of Cl- in the form of HCl, something that diminishes the conductivity because of deprotonation of the polymer chains. In contrast, the simultaneous agglomeration of the materials’ grains improves conductivity. We observe that there coexist two competing mechanisms of electrical conductivity change. The difference in the isothermal curves for temperatures of 100, 300 and 380K, in room atmosphere and in inert He, are linked to the role of these factors: a) The temperature, which determines the mobility of the polymer chains and the excitation of the carriers, as well as the rate of diffusion and the speed of chemical reactions with oxygen and moisture of the air. We have to consider that the glass transition temperature Tg of PPy, above which cooperative movements of the chains occur, varies between 250 and 400K and is strongly dependant on the method of synthesis, the nature of the dopants and their position in the material, either contributing in the chain structure or by forming side chains. b) The existence of oxygen and moisture of the atmosphere, which, as we have mentioned, play an important role in the scission of polymer chains that destroys the conjugated character of the material. c) The existence of TiO2, which is characterized by a higher bang gap than PPy, in higher temperatures contributes to the transfer of oxygen to the polymer leading to the same result as the oxygen of atmospheric air. Especially, the isothermal curves for 100K show the determining role o oxygen and moisture to the diminishing of the conductivity in ambient atmosphere. In addition, in He atmosphere they reveal a conductivity improving mechanism. At 300K, the presence of TiO2 weakens the mechanism responsible for the improvement of conductivity, because the nanoparticles diminish the mobility and therefore the ordering of polymer chains and the increase of conductivity. The maxima that are observed during the first 10min are attributed to the improvement of the chain ordering of the polymer. For longer times, the ageing mechanisms dominate, due to the presence of oxygen and moisture, changes in the structure that sever the carrier pathways, result in diminishing of the conductivity. An exception to the above is the case of pure PPy in inert he atmosphere, where the lack of oxygen and moisture results in the increase of conductivity during all of the ageing process. Completely different behaviour is observed in the PPy/5% w/w TiO2 nanocomposites at 300K in He atmosphere. The diminishing of the conductivity with ageing can be attributed to the transfer of oxygen from TiO2 to the polymer, resulting in scission of the chains and lowering of the conductivity values. In conclusion, at 380K, the appearance on a maximum is less intense and it shows that at this temperature, the conductivity reducing mechanisms are far more dominant, both in room atmosphere as well as in inert He.

Πολυπυρρόλη

Τιτάνια

Αγώγιμα πολυμερή

Γήρανση

Ειδική αγωγιμότητα

Νανοσύνθετα

620.192 028 7

Polypyrrole

Titania

TiO2

Conducting polymers

Ageing

Specific conductivity

Nanocomposites

Extreme water catalyzed transformations of SiO2, TiO2 and LiAlSiO4

Spektor, Kristina

January 2015

The dramatic change in properties of water near its critical point (i.e. T = 374 °C and p = 22.1 MPa, note: 100 MPa = 0.1 GPa = 1 kbar ≈ 1000 atm) has been a subject of numerous studies and also lead to the development of various applications (e.g. in waste destruction, biomass processing, and the synthesis of advanced ceramic materials). However, comparatively little is known about the behavior of water at gigapascal pressures. The present study attempts to explore catalytical properties and reactivity of extreme water with respect to several oxide systems: SiO2, TiO2 and LiAlSiO4. “Extreme water” here is defined as existing at p,T conditions of 0.25–10 GPa and 200–1000 °C, thus considering both supercritical fluid and hot compressed ice. The study shows that extreme water can make high pressure mineral phases accessible at relatively mild T conditions. At the same time, high pressure aqueous environments appear efficient in stabilizing novel metastable structures and may be considered as a general route for synthesizing new materials. The hydrothermal treatment of SiO2 glass at 10 GPa and 300–550 °C yielded an unusual ultrahydrous form of stishovite with up to 3% of structural water. At the same time, the extreme water environment enhanced notably the kinetics of stishovite formation, making it accessible at unprecedentedly low temperatures. Thus, for the SiO2–H2O system water acts as both catalyst and reactant. For TiO2 a hydrothermal high pressure treatment proved to be of high importance for overcoming the kinetical hindrance of the rutile – TiO2-II transformation. 6 GPa and 650 °C were established as the mildest conditions for synthesizing pure TiO2-II phase in less than two hours. The crystallization of LiAlSiO4 glass in an extreme water environment yielded a number of different phases. In the low pressure region (0.25 – 2 GPa) mainly a zeolite (Li-ABW) and a dense anhydrous aluminosilicate (α-eucryptite) were obtained. At pressures above 5 GPa the formation of novel pyroxene-like structures with crystallographic amounts of structural water was observed. The overall conclusion of this study is that extreme water environments show a great potential for catalyzing phase transitions in oxide systems and for stabilizing novel structures via structural water incorporation. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 4: Manuscript.</p>

extreme water environments

high pressure polymorphism

hydrous stishovite

titania phase transitions

lithium aluminosilicates

zeolites from glass precursors

hydrous pyroxenes

Synthèse et caractérisation d’oxyde de titane et de zirconium mésoporeux : applications en catalyse / Synthesis and characterization of mesoporous titanium oxide and zirconium : Application in catalysis

Naboulsi, Issam

10 November 2017

Dans ce travail, nous nous sommes tout d’abord intéressés à l’influence du traitement de la mésophase hybride sous ammoniac et des conditions de cristallisation sur les propriétés d’oxydes de titane mésoporeux. Le protocole de synthèse de ces matériaux a été mis au point auparavant au laboratoire à l’aide d’une méthode combinant le mécanisme transcriptif à partir des cristaux liquides du copolymère bloc P123 et la méthode EISA. Une cristallisation sous atmosphère oxydante, augmente le degré de cristallinité et favorise une croissance des particules d’anatase. En conséquence, la photodégradation du méthylorange, utilisé comme molécule modèle est augmentée. Lorsque la cristallisation est réalisée sous azote pur, l’anatase n’est pas favorisée et la photoactivité est alors gouvernée par la surface spécifique des matériaux. Nous avons également montré qu’au cours de la synthèse, l’interaction de NH3 avec le titane amorphe promeut la formation de la structure rutile de TiO2 et défavorise par conséquent la cristallisation sous forme anatase. Par conséquent lorsque le traitement sous ammoniac de la mésophase hybride est prolongé ou lorsqu’ il est réalisé à pression élevée, l’activité photocatalytique des oxydes de titane, obtenus après cristallisation du TiO2 amorphe sous air synthétique, diminue. L’introduction d’un second niveau de mésoporisité permet d’accroitre l’efficacité des photocatalyseurs, car la diffusion et l’accès aux sites actifs des molécules de colorant sont améliorés. Les matériaux à double mésoporisité présentent une activité photocatalytique deux fois et demie supérieure à celle des oxydes de titane mésoporeux monomodaux. Des catalyseurs pour l’hydrodésulfuration des gazoles ont également étés conçus en dispersant la phase active MoS2 à la surface des oxydes de titane mésoporeux mono- et bimodaux. Le dibenzothiophène (DBT) et le 4,6-diméthylbenzodiophène (46DMDBT) ont été utilisées comme molécules modèles. Contrairement au catalyseur conventionnel MoS2/Al2O3, pour lequel l’hydrodésulfuration se produite selon la voie hydrogénante, grâce à la présence de sites acides de Brönsted, les catalyseurs supportés sur TiO2 mésoporeux favorisent la désulfurisation directe du 46DMDBT. Pour terminer, la méthode de synthèse mise au point pour TiO2 a été transposée à l’oxyde de zirconium. Toutefois, dans ce cas seul un arrangement vermiforme des canaux est obtenu. Ce phénomène est probablement lié à la présence du propanol contenu dans la source du précurseur inorganique. L’incorporation d’étain au sein des zircones mésoporeuses a également été réalisée et nous avons mis en évidence que cet élément est favorable à la cristallisation de ZrO2 / In this work, we have first investigated the effect of both the crystallization conditions and of the hybrid mesophase treatment under ammonia atmosphere on the properties of mesoporous TiO2, for which the preparation was developed previously via a method combining Liquid Crystal Templating (LCT) and EISA mechanisms, using P123 as template. The photocatalysis efficiency of the materials crystallized under oxidizing conditions increases with the calcination temperature thanks to the enhancement of crystallinity and the growth of anatase particles. By contrast, when the crystallization is performed under pure nitrogen the anatase is not favored and the photocatalytic activity is governed by the materials’ specific surface area. We have also shown that during the mesoporous TiO2 synthesis, interactions between ammonia and amorphous titania promote the formation of rutile, which is a drawback for the transformation of amorphous titania into anatase. Consequently, when the treatment under ammonia is prolonged or when it is performed at high NH3 pressure, the activity of the photocatalysts recovered after crystallization under synthetic air decreases. The introduction of a second mesoporosity level enhances the degradation rate. In that case the diffusion and the accessibility of the dye molecules to the active sites are favored. Catalysts for gazole hydrodesulfurization have also been designed by dispersing the active MoS2 phase onto the surface of the mono and dual mesoporous titania. The obtained catalysts have been tested for the hydrodesulfurization of dibenzothiophene (DBT) and 4,6-dimethyldibenzothiophene (46DMDBT), used as model molecules. We highlight that thanks to the intrinsic Brönsted acidity, the CoMoS/mesoporous TiO2 catalysts favor the direct desulfurization route of 46DMDBT, in contrary to the conventional CoMoS/alumina catalyst. The synthesis procedure developed for mesoporous TiO2 has also been adapted for the preparation of mesoporous ZrO2. However, only mesoporous materials with a wormhole-like structure have been obtained. This phenomenon is likely due to the presence of propanol contained in the source of the inorganic precursor. We have also incorporated tin into the zirconia framework. The presence of thin favors the crystallization of ZrO2

Matériaux mésoporeux

Titane

Zirconium

Photocatalyse

Hydrodésulfuration

Gazoles

Mesoporous materials

Titania

Zirconia

Photocatalysis

Hydrodesulfurization

Gasoil

541.395

665.53

620.116

Adição de fósforo (P) em catalisadores NiMo, suportados em γ-Al2O3, Al2O3/TiO2 e TiO2 - efeito na hidrodessulfurização do tiofeno

Zanotello, Tatiane Cristina

18 February 2013

Made available in DSpace on 2016-06-02T19:56:49Z (GMT). No. of bitstreams: 1 4974.pdf: 3642452 bytes, checksum: 9983d14f77babcbd0c76cb3ef274c7c6 (MD5) Previous issue date: 2013-02-18 / Universidade Federal de Sao Carlos / Mo, NiMo or NiMoP HDS catalysts were supported on Al2O3, Al2O3-TiO2 or TiO2. These supports were synthesized via sol-gel and in the case o TiO2 it was used a commercial sample. The active phases were introduced by impregnation. Supports and catalysts in the oxide form were characterized by X-ray diffraction (XRD), diffuse reflectance UV-Vis spectroscopy (DRSUV-Vis), thermogravimetric analyses (TG), temperature-programmed reduction with H2 (TPR-H2), N2 adsorption/desorption, energy dispersive X-ray spectroscopy (EDS), X-ray fluorescence (XRF), temperature-programmed desorption of NH3 (TPD-NH3), high resolution transmission electron microscopy (HRTEM) and evaluated at 300°C in the HDS of thiophene, used as a model molecule. Alumina presented a high specific surface area and meso/macroprous characteristics, allowing a high dispersion of the active phases, as was evidenced by XRD and DRSUV-VIS data. A HRTEM image of a NiMo/Al2O3 catalyst showed the presence of crystalline MoS2 whose activity was substantially promoted by the presence of Ni. The NiMo catalysts were active in the HDS of thiophene, however, the activity was enhanced significantly by the incorporation of P. This result corroborates the positive influence of P in the preparation of HDS catalysts. It was suggested that P must participate as promoter in the formation of the NiMoS phase during the sulfidation process of the Ni and Mo oxides. The supported NiMoP catalysts prepared in this work were more active than a commercial NiMoP/ Al2O3 catalyst, with this result validating the preparation procedures used here. The titania addition in the alumina framework led to NiMo catalysts possessing lower activity. That behavior was attributed to the formation of Ni and Mo sulfides without interaction diminishing the generation NiMoS phase, which is highly active in the HDS of sulfured organic compounds. / Catalisadores para hidrodessulfurização (HDS) contendo Mo, NiMo ou NiMo e o aditivo fósforo (P), foram suportados sobre Al2O3, Al2O3-TiO2 ou TiO2. A alumina e a alumina-titânia foram sintetizadas via sol-gel e, no caso da titânia pura, utilizada uma amostra comercial. A introdução dos sais precursores da fase ativa foi realizada via impregnação. Suportes e catalisadores na forma de óxidos foram caracterizados através de difração de raios X (DRX), espectroscopia por refletância difusa no ultravioleta visível (DRSUV-VIS), termogravimetria (TG), redução com hidrogênio à temperatura programada (RTP-H2), adsorção/dessorção de N2, espectroscopia de energia dispersiva de raios X (EDX), fluorescência de raios X (FRX), dessorção de amônia a temperatura programada (TPD-NH3), microscopia eletrônica de transmissão de alta resolução (HRTEM) e avaliados a 300&#8304;C na HDS do tiofeno. A alumina apresentou uma alta área superficial específica e características meso/macroporosa, possibilitando alta dispersão das fases ativas, conforme evidenciado por DRX e dados de DRSUV-VIS. A imagem de HRTEM do catalisador NiMo/Al2O3 mostrou a presença de MoS2 cuja atividade foi promovida substancialmente pela presença de Ni. Os catalisadores NiMo sobre os suportes utilizados foram ativos no HDS do tiofeno, entretanto, essa atividade foi melhorada pela incorporação de P. Esse resultado ratifica a influência positiva da utilização desse aditivo na preparação de catalisadores de HDS. O fósforo deve atuar como um promotor na formação de espécies NiMoS durante o processo de sulfetação dos óxidos de Mo e Ni. Os catalisadores NiMoP preparados neste trabalho apresentaram atividade específica superior à de um catalisador NiMoP/Al2O3 comercial, o que valida os procedimentos de preparação utilizados no trabalho. A adição de titânia na alumina durante a síntese sol-gel conduziu a catalisadores com menor atividade. Esse resultado foi atribuído à formação de sulfetos de Ni e Mo não interativos, com a consequente diminuição da formação da fase NiMoS de alta atividade no HDS de compostos organo-sulfurados.

Catalisadores

Hidrodessulfurização

Tiofeno

Alumina

Titânia

Fósforo

HDS

Catalisadores NiMo

HDS, Thiophene

Alumina, titania

NiMo catalysts

Phosphorous

ENGENHARIAS::ENGENHARIA QUIMICA

Catalisadores à base de ferro, vanádio e molibdênio suportados em titanatos lamelares e TiO2 comercial na aplicação da reação de NO com NH3

Grosseli, Guilherme Martins

27 October 2011

Made available in DSpace on 2016-06-02T19:56:45Z (GMT). No. of bitstreams: 1 3936.pdf: 2010584 bytes, checksum: 3be708f515e15835c7915065004f5f86 (MD5) Previous issue date: 2011-10-27 / The minimization of emissions of nitrogen oxides (NOx) is a subject of great interest because they cause serious environmental problems affecting human health, flora and fauna. To break down the NOx catalytic reduction of these compounds to N2 has acquired great importance and may occur in the absence or presence of a reducing agent. The selective catalytic reduction using ammonia as a reducing agent (NH3-SCR) has been shown to be one of the most attractive, being used worldwide to control NOx emissions by industries due to its high efficiency, selectivity and low cost. To obtain more efficient catalysts for this reaction, several studies have been developed. In this context, the objective of this work is to prepare, to wet impregnation, catalysts based on vanadium, molybdenum and iron supported on commercial TiO2 and lamellar titanates (TL) with high (A-TL) or low-sodium (B-TL), and apply them to the reduction of NO with NH3.It was also studied the effect of calcination temperature in titanates with low sodium content. Results of XRD and adsorption of N2 measurements confirmed the formation of TL mesoporous structure and high specific surface area. After the addition of metal to TiO2 and TL, it was observed a significant decrease in the values of specific surface areas, attributed to the filling of pores by metal oxides. The RTP-H2 showed lower reducibility of metals supported on the lamellar titanates and commercial TiO2 support. The catalysts supported TL with high sodium content showed lower catalytic activity compared to commercial catalysts . However, the catalysts supported on titanates with low sodium content showed promising results in the conversion of NO to N2. The catalysts Fe2O3/TiO2 Fe2O3/B-TL showed loss of activity in the presence of SO2, which partially regenerates in the absence of the compound. In the presence of water, both catalysts showed a decline in the conversion, With the removal of H2O the Fe2O3/TiO2 showed partial regeneration, while the Fe2O3/B-TL suffered irreversible deactivation. / A minimização das emissões de óxidos de nitrogênio (NOx) é assunto de alto interesse pois causam graves problemas ambientais afetando a saúde humana, à flora e à fauna. Para abater os NOx, a redução catalítica desses compostos a N2 vem adquirindo grande relevância, podendo ocorrer na ausência ou presença de um agente redutor. A redução catalítica seletiva utilizando amônia como agente redutor (RCS-NH3) tem-se mostrado um dos processos mais atrativos, sendo mundialmente aplicado no controle de emissão do NOx pelas indústrias, devido a sua alta eficiência, seletividade e baixo custo. Para a obtenção de catalisadores mais eficientes para essa reação, diversos estudos tem sido desenvolvidos. Nesse contexto, o objetivo deste trabalho é preparar, via impregnação úmida, catalisadores à base de vanádio, molibdênio e ferro suportados em TiO2 comercial e titanatos lamelares (TL) com alto (A-TL) ou (B-TL) baixo teor de sódio, e aplicá-los na redução de NO com NH3. Foi verificado estudado também o efeito da temperatura de calcinação nos titanatos com baixo teor de sódio. Resultados de DRX e medidas de adsorção de N2 confirmaram a formação de TL de estrutura mesoporosa e de alta área superficial específica. Após a adição dos metais aos suportes TiO2 e TL, foi observada uma queda significativa nos valores das áreas superficiais específicas, atribuída ao preenchimento dos poros pelos óxidos metálicos. O RTP-H2 indicou menor redutibilidade dos metais suportados nos titanatos lamelares frente ao suporte TiO2 comercial. Os catalisadores suportados em TL com alto teor de sódio apresentaram atividade catalítica inferior quando comparados aos catalisadores suportados em TiO2 comercial. No entanto, os catalisadores suportados nos titanatos com baixo teor de sódio apresentaram resultados promissores na conversão do NO a N2. Os catalisadores Fe2O3/TiO2 e Fe2O3/B-TL registraram queda parcial na atividade quando na presença do SO2, que se regenera parcialmente na ausência do composto. Na presença de água, ambos catalisadores apresentaram queda na conversão, sendo que, na retirada deste composto, o Fe2O3/TiO2 apresentou parcial regeneração, ao passo que, o Fe2O3/B-TL, sofreu desativação irreversível.

Catalisadores

RCS-NH3

Titanato lamelar

Dióxido de titânio

Abatimento de NO

RCS-NH3

Titania

NOx abatement

Layeres titanates

ENGENHARIAS::ENGENHARIA QUIMICA

Elaboration de photocatalyseurs à base de nanotubes de TiO2 modifiés par WO3 et ZnO : applications à l'élimination de méthyléthylcétone et de l'H2S sous illumination UV-A et solaire / Development of TiO2 nanotube based photocatalysts modified with WO3 and ZnO : applications to elimanation of methylethylketone and H2S under UV-A and solar irradation

Yamin, Yas

20 June 2013

Il est couramment admis que le niveau de pollution dans l'environnement intérieur pouvait dépasser le niveau de pollution extérieur. C’est la raison pour laquelle la qualité de l'air intérieur est devenue une préoccupation sociétale importante en raison de la durée croissante que nous passons dans ces environnements. Les procédés d'oxydation avancée (POA), parmi lesquels l'oxydation photocatalytique, sont des techniques pertinentes pour la purification de l'air. En photocatalyse, les nanotubes de titane montrent un intérêt tout particulier en raison de leurs propriétés intrinsèques spécifiques de par leurstructure tubulaire. Ce matériau unidimensionnel engendre un rapport surface/volume important qui donne accès à une surface spécifique et à des capacités d’adsorption importantes, mais aussi à des propriétés de transport électronique accrues. Deux molécules modèles gazeuses ont été retenues, la méthyléthylcétone (MEC) et le sulfure de dihydrogène (H2S). Ces molécules diffèrent de par leur composition chimique (présence ou non d’hétéroatomes) et leurs propriétés physico-chimiques et reflètent différentes catégories de pollutions chimiques et olfactives. Afin d’améliorer les performances photocatalytiques des nanotubes, de TiO2 synthétisés par méthode hydrothermale, que ce soit sous illumination UV-A ou solaire, des modifications avec un autre semi-conducteur WO3 ou ZnO ont été entreprises. Les mêmes modifications ont également été réalisées sur le photocatalyseur commercial TiO2 P25 (Evonik). Une des finalités de ce travail est la corrélation des conditions de synthèse de ces matériaux avec leurs caractéristiques physico-chimiques et avec leurs propriétés photocatalytiques vis-àvis de l’élimination des deux polluants étudiés. Une approche mécanistique a également été menée. / Indoor air quality has become an important social concern due to the increased amount of time spent in indoor environment. It is now well admitted that the pollution level in indoor environment could exceed the pollution level outdoor. Advanced Oxidation Processes (AOP), such as photocatalytic oxidation, are promising technologies for air purification. The synthesis and applications of high aspect ratio onedimensional titania-based nanostructures have attracted increasing attention. In photocatalysis, titania nanotubes have already shown enhanced photocatalytic efficiency over nanoparticles, enabled by highersurface area, tubular structure with higher charge carriers generation and transfer efficiency. However, together with visible light activation, higher efficiency is a challenging task. The fundamental challenges are to develop controlled and self-assembled 1D-TiO2-based nanostructures for improving the light absorption, generation and transfer of electrons and specific surface area. In this thesis, two model gas molecules were used, methyl ethyl ketone (MEK) and dihydrogen sulfide (H2S). These molecules differ in their chemical composition (presence or absence of heteroatoms) and their physico-chemical properties and reflect different types of chemical and odor pollutions. In order to improve the photocatalyticperformance of TiO2 nanotubes synthesized by the hydrothermal method, either under UV-A or solar illumination, modifications with another semiconductor, WO3 or ZnO, were made. The same modifications were also made on the commercial photocatalyst TiO2 P25 (Evonik). One of the aims of this study is the correlation of synthesis conditions of these materials with their physico-chemical properties and their photocatalytic properties regarding the elimination of the two pollutants studied. A mechanistic approach was also conducted.

Nanotubes de TiO2

Modification avec WO3 et ZnO

Méthyléthylcétone

H2S

Titania nanotubes

Modification with WO3 and ZnO

Methylethylketone

H2S

541.39

Instabilités thermoconvectives pour des fluides complexes. / Thermal convective instability for complex fluids

Haddad, Zoubida

16 December 2015

La controverse concernant les mécanismes proposés pour l’intensification de la conductivité thermique et de la forte augmentation de la viscosité suggère que les expériences avec des nanofluides bien dispersés et correctement caractérisés seraient intéressantes. Par conséquent, nous nous sommes fixés comme objectif la caractérisation de la conductivité thermique et la viscosité de deux nanofluides “eau-oxyde de silice“ et “eau-titanium“. Il a été observé que la conductivité thermique des deux nanofluides considérés concorde bien avec la théorie du milieu effectif, à savoir, le modèle de Maxwell, et ne montre aucune amélioration par rapport aux effets associés aux mécanismes proposés de l’intensification du transfert du nanofluide tels que le mouvement brownien ou l’effet de stratification. Pour confirmer ce résultat, nous avons également mesuré la conductivité thermique du nanofluide eau contenant une suspension de nanotubes de carbone NTC. Nous constatons que la conductivité thermique de ce nanofluide NTC est également en bon accord avec le modèle de Maxwell. Les disparités et les incohérences publiées par les différents groupes sur les résultats et modèles de la conductivité thermique ainsi que la viscosité du nanofluide se trouvent être principalement dues à la qualité du nanofluide telles que la stabilité colloïdale, la taille des particules, la formation des agrégats, etc… Par ailleurs, l’influence des incertitudes en raison de l’adoption de différents modèles sur le transfert de chaleur par convection naturelle a été étudiée. Il a été observé que les incertitudes dans les modèles prédictifs peuvent conduire à des évaluations erronées du transfert convectif. / The controversy regarding the proposed mechanisms of the exceptionally enhanced thermal conductivity of nanofluids, as well as sharp increase of nanofluid viscosity suggest that systematic experiment with well dispersed and well characterized nanofluids are highly desired. Therefore, on the basis of this suggestion, thermal conductivity and viscosity of silica-water and titania-water nanofluids were measured. It was observed that the thermal conductivity of both nanofluids agrees well with the effective medium theory, i.e., Maxwell model, and does not show any enhancement due to effects associated with the proposed mechanisms of thermal energy transfer in nanofluids like Brownian motion or liquid layering. To support these results, the thermal conductivity of water based nanofluid containing carbon nanotubes was measured. It was found that that thermal conductivity of CNTs nanofluids agrees well with Maxwell model up to 1 vol.%. The inconsistencies in the reported thermal conductivity and dynamic viscosity from different research groups are found to be mainly due to the characterization of the nanofluid, including determination of colloidal stability and particle size, (i.e, aggregates size) within nanofluid. The influence of uncertainties due to adopting various formulas for the dynamic viscosity on natural convection heat transfer was investigated. It was observed that uncertainties in the predictive models for the effective thermal conductivity and dynamic viscosity of nanofluids, leads to erroneous evaluation of the convective heat transfer with nanofluids, and this acts as a brake on research in the area.

Nanofluide

Titanium

Silice

Conductivité thermique

Viscosité

Transfert de chaleur convectif

Nanofluid

Titania

Silica

Thermal conductivity

Viscosity

Convective heat transfer

Electrochemical Detection Of Proteins : Myoglobin As A Case Study

Narayan, Karthik K

11 1900

An effective electrochemical sensor for myoglobin (Myb) detection was developed using a simple procedure of denaturing the protein with guanidine hydrochloride and detecting the released heme group by cyclic voltammetry. The concentration of denaturant was optimized to obtain maximum current response for the analyte (Myb). To improve the sensitivity of the sensor, the working electrode, glassy carbon electrode was modified with a layer of Titania nanotubes (TNT). The direct electrochemical behavior of the modified electrode (TNT-GCE) was studied using cyclic voltammetry (CV). The performance of the sensor was investigated and optimized and the system was evaluated by monitoring the Myb concentration. Despite the reduced current response for the modified electrode compared to bare GCE, the sensitivity of the system was improved significantly by overcoming the large background current due to denaturant. The developed TNT modified electrode improved the detection limit of Myb and showed good stability, sensitivity and reproducibility. Under optimal conditions, the catalytic currents are linearly proportional to the concentrations of Myb in the wide range from 50 nM to 6 M. This approach provides improved sensitivity in the given range, and may provide a novel and efficient platform for the fabrication of sensors for other heme proteins.

Electrochemical Sensors

Proteins - Electrochemical Detection

Myoglobins - Electrochemical Detection

Myoglobin

Proteins as Biomarkers

Titania Nanotubes (TNT)

Heme Proteins

Myb

Biochemistry

Electrodeposition of Polymer Electrolytes into Titania Nanotubes as Negative Electrode for 3D Li-ion Microbatteries

Plylahan, Nareerat

29 October 2014

Des nanotubes de dioxyde de titane (TiO2nts) sont étudiés comme électrodes négatives potentielles pour des microbatteries Li-ion 3D. Ces TiO2nts lisses et hautement auto-organisés sont élaborés par anodisation du Ti dans des électrolytes organiques à base de glycérol ou d'éthylène glycol contenant des ions fluor et de l'eau en faible quantité. Les structures présentant un diamètre de 100 nm et une longueur variant de 1,5 à 14 µm sont particulièrement appropriés pour l'application visée. Les TiO2nts ont été tapissés de manière conforme par un électrolyte polymère (PMA-PEG) comportant un sel de lithium (LiTFSI) grâce à la technique d'électropolymérisation. Les études morphologiques menées par SEM et TEM ont montré que les nanotubes sont entièrement recouverts d'un film mince polymère de 10 nm d'épaisseur, ce qui permet de préserver la structure 3D de l'électrode. Les tests électrochimiques portant sur les nanotubes seuls ainsi que sur les TiO2nts tapissés d'électrolyte polymère ont été effectués en demi-cellule et en cellule complète en utilisant un électrolyte polymère à base de MA-PEG contenant du LiTFSI. En demi-cellule, les TiO2nts de 1,5 µm de long delivrent une capacité surfacique de 22 µAh cm-2 relativement stable sur 100 cycles. La performance de la demi-cellule est améliorée de 45% à une cinétique de 1C lorsque les TiO2nts sont tapissés de manière conforme par un electrolyte polymère (PMA-PEG). Cet effet résulte d'un meilleur transport de charges lié à l'augmentation de la surface de contact entre l'électrode et l'électrolyte. / Titania nanotubes (TiO2nts) as potential negative electrode for 3D lithium-ion microbatteries have been reported. Smooth and highly-organized TiO2nts are fabricated by electrochemical anodization of Ti foil in glycerol or ethylene glycol electrolyte containing fluoride ions and small amount of water. As-formed TiO2nts shows the open tube diameter of 100 nm and the length from 1.5 to 14 µm which are suitable for the fabrication of the 3D microcbatteries. The deposition of PMA-PEG polymer electrolyte carrying LiTFSI salt into TiO2nts has been achieved by the electropolymerization reaction. The morphology studies by SEM and TEM reveal that the nanotubes are conformally coated with 10 nm of the polymer layer at the inner and outer walls from the bottom to the top without closing the tube opening. 1H NMR and SEC show that the electropolymerization leads to PMA-PEG that mainly consists of trimers. XPS confirms the presence of LiTFSI salt in the oligomers.The electrochemical studies of the as-formed TiO2nts and polymer-coated TiO2nts have been performed in the half-cells and full cells using MA-PEG gel electrolyte containing LiTFSI in Whatman paper as separator. The half-cell of TiO2nts (1.5 µm long) delivers a stable capacity of 22 µAh cm-2 over 100 cycles. The performance of the half-cell is improved by 45% at 1C when TiO2nts are conformally coated with the polymer electrolyte. The better performance results from the increased contact area between electrode and electrolyte, thereby improving the charge transport.

Batterie lithium-Ion

Nanotubes de dioxyde de titane

Électrolyte polymère

Microbatteries

Lithium-Ion batteries

Titania nanotubes

Polymer electrolyte

Microbattery

539