Investigation Of Supported Metal Catalysts And Ferrites By Exafs And Cognate Techniques

Turaga, Arunarkavalli

08 1900

No description available.

Catalysts

Ferrites

Critical Temperature

Metal Catalysts

Nickel Catalysts

Electrochemistry

The Challenge of Selectivity in Ethylene Oligomerization: Ligand Design and Metal Valence States

Thapa, Indira

January 2012

Catalytic ethylene oligomerization is a well understood industrially viable process. The large majority of scientific literature and patents concerning this process has been developed with the use of chromium catalysts. Commercial systems producing selective tri/tetramerization, non-selective oligomerization and polymerization are all based on this metal with the exception of a few systems based on other transition metals (Zr, Ti, Ni etc.). This versatility raises interesting questions about chromium’s unique behaviour. Essentially, selective or non-selective oligomerization and polymerization processes could be regarded as belonging to the same category of C-C bond forming reactions, though different mechanisms are involved. The first part of this thesis explores a variety of chromium complexes for ethylene oligomerization purposes. In order to gather further information about the unique behaviour of chromium, we have explored a variety of nitrogen and phosphorus containing ligands. We started with a simple bi-dentate anionic amidophosphine (NP) ligand and assessed the role of the ligand’s negative charge and number of donor atoms in determining the type of catalytic behaviour in relation to the metal oxidation state. This ligand proved capable of generating a series of chromium dimeric, tetrameric or polymeric and even heterobimetallic chromium-aluminate complexes in different valence states. This allowed us to isolate a “single component” self activating Cr(II) complex as well as a rare example of mixed valence Cr(I)/Cr(II) species. Additionally, each of these species acted as switchable catalyst depending on the type of co-catalyst

selective

trimerization

tetramerization

ethylene oligomerization

polymerization

dimerization

chromium catalysts

Nickel catalysts

Catalisadores de Ni suportados em Al2O3 modificados com V, Nb e Zn aplicados na reforma à vapor do ácido butírico para produção de H2 / Nickel catalysts supported in al2o3 modified with v, nb and zn applied in the steam reform of butyric acid for h2 production

Matos, Thaisa Moreira de

10 April 2017

O hidrogênio é visto como um importante combustível alternativo aos combustíveis convencionais, como a gasolina e o óleo diesel, devido a sua alta eficiência energética e não geração de poluentes. Porém, a maior parte do hidrogênio produzido é proveniente de fontes não renováveis, como o gás natural e o petróleo. Novas tecnologias para a geração de hidrogênio vem sendo estudadas e dentre elas se destaca a reação de reforma a vapor de compostos oxigenados. Os ácidos graxos voláteis gerados durante o tratamento anaeróbio de águas residuárias constitui uma matéria-prima interessante para a produção de hidrogênio a partir de biomassa. Os principais produtos gerados no tratamento de águas residuárias são o etanol, o ácido acético e o ácido butírico, este, chega a representar 35 % em massa podendo ser utilizado como molécula modelo na reação de reforma a vapor. Neste trabalho, foram desenvolvidos catalisadores a base de níquel (Ni) modificados com vanádio (V), zinco (Zn) e nióbio (Nb) suportados em alumina (γ-Al2O3), visando minimizar os depósitos carbonáceos, assim como aumentar a atividade e seletividade para o hidrogênio na reação de reforma a vapor do ácido butírico. Os catalisadores foram modificados com diferentes teores de V, Zn e Nb (2,5, 5 e 10 % em massa). Nas reações feitas a 600 ºC utilizando razão estequiométrica ácido butírico:vapor, dentre os catalisadores modificados com V, o com 5 % (10Ni2,5VAl2O3) apresentou o melhor desempenho, chegando a uma conversão de 86 % para o ácido butírico, além de aumentar a estabilidade do catalisador quando comparado ao catalisador contendo apenas Ni (10NiAl2O3). Para o grupo de catalisadores modificados com Zn, o catalisador com 10 % em massa de Zn (10Ni10ZnAl2O3) apresentou uma conversão de 83 %, sendo este grupo o com menor taxa de formação de carbono. Dentre os catalisadores modificados com Nb, o com menor teor (10Ni2,5NbAl2O3) foi o que apresentou o melhor desempenho, alcançado uma conversão de 82 %. Testes catalíticos utilizando excesso de água mostraram alta conversão, superiores a 90 %, e alta seletividade para H2. Dessa forma, a adição de metais com diferentes propriedades pode contribuir para uma maior seletividade para hidrogênio, seja pela redução dos depósitos de carbono ou pela melhora na estabilidade catalítica.  / Hydrogen is an important alternative fuel to conventional fuels, such as gasoline and diesel, due to its high energy efficiency and non-generation of pollutants. However, most of the hydrogen produced comes from non-renewable sources such as natural gas and diesel oil. New technologies for the generation of hydrogen have been studied, among them the reaction of steam reforming of oxygenated compounds. Volatile fatty acids generated during the anaerobic treatment of wastewater are an interesting raw material for the production of hydrogen from biomass. The main products generated in the treatment of wastewater are ethanol, acetic acid and butyric acid, which represents 35% by mass and can be used as a model molecule in the steam reforming reaction. In this work, nickel-based (Ni) catalysts modified with vanadium (V), zinc (Zn) and niobium (Nb) supported on alumina (γ-Al2O3) were developed, aiming at minimizing carbonaceous deposits, as well as increasing activity and selectivity for the hydrogen in the steam reforming reaction of butyric acid. The catalysts were modified with different levels of V, Zn and Nb (2.5, 5 and 10 % by mass). In the reactions made at 600 ºC using stoichiometric butyric acid: steam ratio, among the catalysts modified with V, the 5 % (10Ni2,5VAl2O3) showed the best performance, reaching a conversion of 86 % to butyric acid, besides increasing The stability of the catalyst when compared to the catalyst containing only Ni (10NiAl2O3). For the group of catalysts modified with Zn, the catalyst with 10 % by mass of Zn (10Ni10ZnAl2O3) showed a conversion of 83 %, this group being the one with the lowest rate of carbon formation. Among the catalysts modified with Nb, the one with the lowest content (10Ni2,5NbAl2O3) was the one that presented the best performance, achieving a conversion of 82 %. Catalytic tests using excess water showed high conversion, higher than 90%, and high selectivity for H2. Thus, the addition of metals with different properties may contribute to a higher selectivity for hydrogen, either by reducing carbon deposits or by improving catalytic stability.

ácido butírico

butyric acid

catalisadores de níquel

Catálise heterogênea

Heterogeneous catalysis

hidrogênio

hydrogen

nickel catalysts

Reforma a vapor

Steam reforming

Catalisadores de Ni suportados em Al2O3 modificados com V, Nb e Zn aplicados na reforma à vapor do ácido butírico para produção de H2 / Nickel catalysts supported in al2o3 modified with v, nb and zn applied in the steam reform of butyric acid for h2 production

Thaisa Moreira de Matos

10 April 2017

O hidrogênio é visto como um importante combustível alternativo aos combustíveis convencionais, como a gasolina e o óleo diesel, devido a sua alta eficiência energética e não geração de poluentes. Porém, a maior parte do hidrogênio produzido é proveniente de fontes não renováveis, como o gás natural e o petróleo. Novas tecnologias para a geração de hidrogênio vem sendo estudadas e dentre elas se destaca a reação de reforma a vapor de compostos oxigenados. Os ácidos graxos voláteis gerados durante o tratamento anaeróbio de águas residuárias constitui uma matéria-prima interessante para a produção de hidrogênio a partir de biomassa. Os principais produtos gerados no tratamento de águas residuárias são o etanol, o ácido acético e o ácido butírico, este, chega a representar 35 % em massa podendo ser utilizado como molécula modelo na reação de reforma a vapor. Neste trabalho, foram desenvolvidos catalisadores a base de níquel (Ni) modificados com vanádio (V), zinco (Zn) e nióbio (Nb) suportados em alumina (γ-Al2O3), visando minimizar os depósitos carbonáceos, assim como aumentar a atividade e seletividade para o hidrogênio na reação de reforma a vapor do ácido butírico. Os catalisadores foram modificados com diferentes teores de V, Zn e Nb (2,5, 5 e 10 % em massa). Nas reações feitas a 600 ºC utilizando razão estequiométrica ácido butírico:vapor, dentre os catalisadores modificados com V, o com 5 % (10Ni2,5VAl2O3) apresentou o melhor desempenho, chegando a uma conversão de 86 % para o ácido butírico, além de aumentar a estabilidade do catalisador quando comparado ao catalisador contendo apenas Ni (10NiAl2O3). Para o grupo de catalisadores modificados com Zn, o catalisador com 10 % em massa de Zn (10Ni10ZnAl2O3) apresentou uma conversão de 83 %, sendo este grupo o com menor taxa de formação de carbono. Dentre os catalisadores modificados com Nb, o com menor teor (10Ni2,5NbAl2O3) foi o que apresentou o melhor desempenho, alcançado uma conversão de 82 %. Testes catalíticos utilizando excesso de água mostraram alta conversão, superiores a 90 %, e alta seletividade para H2. Dessa forma, a adição de metais com diferentes propriedades pode contribuir para uma maior seletividade para hidrogênio, seja pela redução dos depósitos de carbono ou pela melhora na estabilidade catalítica.  / Hydrogen is an important alternative fuel to conventional fuels, such as gasoline and diesel, due to its high energy efficiency and non-generation of pollutants. However, most of the hydrogen produced comes from non-renewable sources such as natural gas and diesel oil. New technologies for the generation of hydrogen have been studied, among them the reaction of steam reforming of oxygenated compounds. Volatile fatty acids generated during the anaerobic treatment of wastewater are an interesting raw material for the production of hydrogen from biomass. The main products generated in the treatment of wastewater are ethanol, acetic acid and butyric acid, which represents 35% by mass and can be used as a model molecule in the steam reforming reaction. In this work, nickel-based (Ni) catalysts modified with vanadium (V), zinc (Zn) and niobium (Nb) supported on alumina (γ-Al2O3) were developed, aiming at minimizing carbonaceous deposits, as well as increasing activity and selectivity for the hydrogen in the steam reforming reaction of butyric acid. The catalysts were modified with different levels of V, Zn and Nb (2.5, 5 and 10 % by mass). In the reactions made at 600 ºC using stoichiometric butyric acid: steam ratio, among the catalysts modified with V, the 5 % (10Ni2,5VAl2O3) showed the best performance, reaching a conversion of 86 % to butyric acid, besides increasing The stability of the catalyst when compared to the catalyst containing only Ni (10NiAl2O3). For the group of catalysts modified with Zn, the catalyst with 10 % by mass of Zn (10Ni10ZnAl2O3) showed a conversion of 83 %, this group being the one with the lowest rate of carbon formation. Among the catalysts modified with Nb, the one with the lowest content (10Ni2,5NbAl2O3) was the one that presented the best performance, achieving a conversion of 82 %. Catalytic tests using excess water showed high conversion, higher than 90%, and high selectivity for H2. Thus, the addition of metals with different properties may contribute to a higher selectivity for hydrogen, either by reducing carbon deposits or by improving catalytic stability.

ácido butírico

catalisadores de níquel

Catálise heterogênea

hidrogênio

Reforma a vapor

butyric acid

Heterogeneous catalysis

hydrogen

nickel catalysts

Steam reforming

Obtenção de catalisadores baseados em lantânio, níquel e/ou rutênio para a reforma a vapor da glicerina

Lima, Juliane de Brito

24 November 2014

Submitted by Ana Hilda Fonseca (anahilda@ufba.br) on 2016-09-26T13:21:16Z No. of bitstreams: 1 Versão final_Juliane Lima.pdf: 3005841 bytes, checksum: ce8a2d085212284f1f3504f349cae58c (MD5) / Approved for entry into archive by Vanessa Reis (vanessa.jamile@ufba.br) on 2016-09-26T14:18:35Z (GMT) No. of bitstreams: 1 Versão final_Juliane Lima.pdf: 3005841 bytes, checksum: ce8a2d085212284f1f3504f349cae58c (MD5) / Made available in DSpace on 2016-09-26T14:18:35Z (GMT). No. of bitstreams: 1 Versão final_Juliane Lima.pdf: 3005841 bytes, checksum: ce8a2d085212284f1f3504f349cae58c (MD5) / CNPq / O biodiesel é um combustível limpo derivado de fontes renováveis, óleos vegetais ou gordura animal. Na sua produção, cerca de 10% em massa do óleo vegetal utilizado como insumo é convertido em glicerina, existindo, dessa forma, grande incentivo para a utilização deste subproduto. Por outro lado, a reforma a vapor da glicerina é um processo com grande potencial para a produção de hidrogênio destinado às células a combustível e aos motores de combustão interna. De modo a obter catalisadores alternativos para a reforma a vapor de glicerina, neste trabalho, foram preparados sólidos baseados em níquel e/ou rutênio suportado(s) em óxido de lantânio a partir de dois métodos: (i) impregnação de nitrato de níquel e/ou de rutênio em óxido de lantânio para obter amostras do tipo (NiO)1-x(RuO)x/La2O3 e (ii) decomposição de sólidos com estruturas perovskita do tipo LaNi1-xRuxO3 (x= 0, 0,1 e 1). Os catalisadores foram obtidos por redução desses precursores a 650, 800 ou 1000 oC, dependendo do método de preparação ou amostra, sob fluxo de hidrogênio. As amostras foram caracterizadas por espectroscopia no infravermelho com transformada de Fourier, difração de raios X, medida de área superficial específica e redução à temperatura programada. A avaliação dos catalisadores na reação de reforma a vapor do glicerol (como molécula modelo) foi conduzida sob pressão atmosférica a 600 ºC, por 5 h. Após a reação, determinou-se o teor de coque depositado sobre os catalisadores. Os sólidos obtidos por impregnação, constituídos por óxido de lantânio, óxido de rutênio, óxido de níquel (NiO) e/ou de compostos de níquel e lantânio (LaNiO3 e La2NiO4), apresentaram áreas superficiais específicas baixas (1,5-11 m².g-1). No caso das amostras obtidas por aquecimento de perovskitas, houve a formação de sólidos com estruturas cristalinas com simetria romboédrica ou ortorrômbica, com áreas superficiais específicas ainda mais baixas (0,5-4,7 m².g-1). Esses sólidos foram mais redutíveis que aqueles obtidos por impregnação e, em todos os casos, o rutênio aumentou a redutibilidade dos sólidos. A atividade e seletividade dos catalisadores obtidos variaram com o método de preparação e a composição dos catalisadores. Quando introduzido no catalisador por impregnação, o rutênio diminuiu a atividade do catalisador de níquel, que foi aumentada no sólido oriundo de perovskitas. As conversões variaram de 68 a 97 % e, em todos os casos, o níquel foi mais ativo que o rutênio. O rendimento a hidrogênio também variou com a presença do rutênio e com o método de preparação dos sólidos. Quando preparados por impregnação, os catalisadores monometálicos conduziram a valores mais elevados que os bimetálicos. Quando obtidos por decomposição de perovskitas, o catalisador isento de níquel levou aos mais baixos valores de rendimento, enquanto aquele contendo os dois metais levou ao valor mais elevado. A presença de rutênio diminui a quantidade de coque formado sobre os catalisadores, durante a reforma a vapor da glicerina, apenas quando os sólidos foram obtidos por impregnação. A amostra contendo níquel e rutênio, e obtida por decomposição de perovskitas, foi o catalisador mais promissor, conduzindo a uma conversão de 97%, rendimento a hidrogênio de 76%. / Biodiesel is a clean renewable fuel derived from vegetable oils or animal fat. About 10% by weight of vegetable oil used as a feedstock is converted into glycerin in its production and thus its use is largely encouraged. On the other hand, the steam reforming of glycerin is a great potential process for the production of hydrogen to feed fuel cells and internal combustion engines. In order to obtain alternative catalysts for steam reforming of glycerin nickel and/or ruthenium supported on lanthanum oxide were prepared in this work by two methods: (i) by impregnation of nickel nitrate and/or ruthenium on lanthanum oxide to obtain (NiO)1-x(RuO)x/La2O3 samples and (ii) by decomposition of solids with perovskite-type structures such as LaNi1-xRuxO3 (x = 0, 0.1 and 1). The catalysts were obtained by reduction of these precursors at 650, 800 or 1000 oC, depending on the method of preparation or sample under hydrogen flow. The samples were characterized by Fourier transform infrared spectroscopy, X- ray diffraction, specific surface area measurements and temperature programmed reduction. The catalysts were evaluated in steam reforming of glycerol (as a molecule model) under atmospheric pressure at 600 oC, for 5 h. After reaction, the coke deposited on the catalyst was determined. The solids obtained by impregnation consisted of lanthanum oxide, ruthenium oxide, nickel (NiO) and/or nickel and lanthanum compounds (LaNiO3 and La2NiO4) oxide, showed low specific surface areas (1.5-11 m². g-1). In the case of the samples prepared by heating perovskites, solid crystalline structures with rhombohedral or orthorhombic symmetry were obtained with specific surface areas even lower (0.5-4.7 m².g-1). These solids were more reducible than those obtained by impregnation and ruthenium increased the reducibility of the solids for all cases,. The activity and selectivity of the catalysts changed with the preparation method and with the catalysts composition. When introduced into the catalyst by impregnation, ruthenium decreased the activity of the nickel-based catalyst, whose activity increased in the solid originating from perovskites. The conversions ranged from 68 to 97% and nickel was more active than ruthenium for all cases. The hydrogen yield also varied depending on ruthenium and on the preparation method of the solid. When prepared by impregnation, the monometallic catalysts led to higher values than the bimetallic ones When obtained by decomposition of perovskite, the free-nickel catalyst led to lower yields while those containing the two metals led to the highest value. The presence of ruthenium reduces the amount of coke formed on the catalyst during the steam reforming of glycerin, only when the solids were prepared by impregnation. The sample containing nickel and ruthenium and obtained by decomposition of perovskites was the most promising catalyst, leading to a conversion of 97%, hydrogen yield 76%.

Físico Química

Glicerina

Hidrogênio

Reforma a vapor

Catalisadores de níquel

Catalisadores de rutênio

Glycerin

Hydrogen

Steam reforming

Nickel catalysts

Ruthenium catalysts

Αναμόρφωση βιοκαυσίμων για την παραγωγή υδρογόνου / Reformation of biofuels for hydrogen production

Μπασαγιάννης, Αριστείδης

08 November 2007

Στην παρούσα διατριβή μελετάται η δυνατότητα αναμόρφωσης βιοκαυσίμων με ατμό, και συγκεκριμένα του βιοελαίου και της βιοαιθανόλης, με σκοπό την παραγωγή ρεύματος πλούσιου σε υδρογόνο για την τροφοδοσία κυψελίδων καυσίμου. Η χρήση υδρογόνου σε κυψελίδες καυσίμου αποτελεί μια από τις πλέον υποσχόμενες διεργασίες για την παραγωγή ενέργειας τόσο σε σταθερές όσο και σε κινητές εφαρμογές. Το υδρογόνο ως καύσιμο έχει το πλεονέκτημα ότι δεν παράγει ρυπαντικές ουσίες για την ατμόσφαιρα κατά την παραγωγή ενέργειας, ενώ οι κυψελίδες καυσίμου αποδίδουν πολύ μεγαλύτερη απόδοση σε σχέση με τις συμβατικές μηχανές εσωτερικής καύσης. Όταν δε το υδρογόνο προέρχεται από τη βιομάζα, οι εκπομπές στην ατμόσφαιρα σε CO2 είναι μηδενικές, αφού το ισοζύγιο του άνθρακα παραμένει κλειστό, μη επιβαρύνοντας έτσι το φαινόμενο του θερμοκηπίου. Το βιοέλαιο και η βιοαιθανόλη ανήκουν στην κατηγορία των βιοκαυσίμων, αφού προέρχονται από τη βιομάζα, και συγκεκριμένα παράγονται μέσω της πυρόλυσης και της ζύμωσής της, αντίστοιχα. Η αντίδραση αναμόρφωσής τους με ατμό είναι εφικτή από θερμοδυναμικής απόψεως, ενώ η απόδοση της συγκεκριμένης διεργασίας σε υδρογόνο είναι αρκετά υψηλή. Θερμοδυναμικά, η αντίδραση αναμόρφωσης ευνοείται σε υψηλές θερμοκρασίες και μικρές πιέσεις. Λόγω της πολυπλοκότητας του βιοελαίου, που αποτελεί μίγμα εκατοντάδων οξυγονούχων οργανικών ενώσεων, αρχικά επιλέγονται πρότυπες ενώσεις αντιπροσωπευτικές αυτού. Ως τέτοια επιλέχθηκε το οξικό οξύ που βρίσκεται σε σημαντικά ποσοστά (~10%) στο βιοέλαιο. Δοκιμάστηκαν διάφοροι υποστηριγμένοι καταλύτες μετάλλων για την ενεργότητά τους στην αντίδραση αναμόρφωσης του οξικού οξέος με ατμό. Διάφοροι παράμετροι που επιδρούν στην καταλυτική ενεργότητα και εκλεκτικότητα διερευνήθηκαν υπό συνθήκες αντίδρασης, όπως η σύσταση του καταλύτη (επίδραση της φύσης του μετάλλου και του φορέα), η θερμοκρασία αντίδρασης και ο χρόνος αντίδρασης. Η μεταλλική φάση των καταλυτών αυτών αποτελούνταν από διάφορα μέταλλα, όπως Pt, Pd, Rh, Ru και Ni, τα οποία ήταν διασπαρμένα σε διάφορους φορείς μεταλλικών οξειδίων, όπως Al2O3, La2O3/Al2O3, MgO/Al2O3 και CeO2/Al2O3. Βρέθηκε ότι οι καταλύτες Ru και Ni παρουσιάζουν την υψηλότερη ενεργότητα και εκλεκτικότητα προς παραγωγή υδρογόνου. Ιδιαίτερα, οι καταλύτες Ru που είναι εναποτεθιμένοι σε φορείς La2O3/Al2O3 και MgO/Al2O3 επιδεικνύουν και πολύ καλή σταθερότητα συναρτήσει του χρόνου αντίδρασης. Επιπλέον, υπολογίστηκε ο ρυθμός εναπόθεσης άνθρακα στην καταλυτική επιφάνεια κατά τη διάρκεια της αντίδρασης και βρέθηκε ότι επηρεάζεται ισχυρά από τη φύση του καταλυτικού υλικού. Η διερεύνηση του δικτύου αντιδράσεων που λαμβάνουν χώρα υπό συνθήκες αναμόρφωσης του οξικού οξέος με ατμό, παρουσία καταλυτών νικελίου αλλά και των φορέων Al2O3 και La2O3, έγινε με τη χρήση δυναμικών τεχνικών με φασματογράφο μάζας, αλλά και τεχνικών μόνιμης κατάστασης. Το οξικό οξύ αλληλεπιδρά έντονα με το φορέα Al2O3 και λιγότερο έντονα με το La2O3. Σε ενδιάμεσες θερμοκρασίες, οι κύριες αντιδράσεις που πραγματοποιούνται είναι αυτές της διάσπασης και της κετονοποίησης του οξικού οξέος, ενώ σε υψηλότερες αυτές της αναμόρφωσης του οξικού οξέος και της μετατόπισης του CO. Παρουσία του Ni, η ενεργότητα μετατοπίζεται σημαντικά προς χαμηλότερες θερμοκρασίες. Το νικέλιο προωθεί τις αντιδράσεις αναμόρφωσης και επιβραδύνει το ρυθμό εναπόθεσης άνθρακα στην καταλυτική επιφάνεια. Επίσης, βρέθηκε ότι η εναπόθεση άνθρακα ευνοείται σε χαμηλές θερμοκρασίες, όξινους φορείς και μεγάλους λόγους τροφοδοσίας άνθρακα-ατμού. Αντίστοιχα δυναμικά πειράματα, για τη διερεύνηση του δικτύου αντιδράσεων υπό συνθήκες αντίδρασης, πραγματοποιήθηκαν και σε καταλύτες Ru διασπαρμένους σε φορείς Al2O3 και MgO/Al2O3. Και σε αυτή την περίπτωση, σε ενδιάμεσες θερμοκρασίες ευνοείται η αντίδραση κετονοποίησης και σε μικρότερο βαθμό αυτή της διάσπασης του οξικού οξέος. Παρουσία του ρουθηνίου η ενεργότητα μετατοπίζεται προς χαμηλότερες θερμοκρασίες και παρατηρείται παραγωγή υδρογόνου με υψηλούς ρυθμούς. Το ρουθήνιο προωθεί τις αντιδράσεις αναμόρφωσης και επιβραδύνει το ρυθμό εναπόθεσης άνθρακα στην καταλυτική επιφάνεια. Επίσης, διερευνήθηκε ο ρόλος του MgO στον καταλύτη Ru/MgO/Al2O3 και εάν και πώς η παρουσία του επιδρά θετικά στην ενεργότητα του συγκεκριμένου καταλύτη. Βρέθηκε ότι η αντίδραση των οξειδίων του αλουμινίου και μαγνησίου είναι πλήρης, οδηγώντας στο σχηματισμό ενός σπινελίου μαγνησίου-αλουμινίου. Η αυξημένη ενεργότητα του καταλύτη Ru/MgO/Al2O3, σε σύγκριση με τον Ru/Al2O3, σχετίζεται με το γεγονός ότι το σπινέλιο Mg-Al προσφέρει αυξημένη κινητικότητα των ιόντων Ο- και ΟΗ- (spillover) από το φορέα στο μέταλλο, μειωμένη οξύτητα σε σύγκριση με το φορέα Al2O3, καθώς και αυξημένη ικανότητα στον καταλύτη για προσρόφηση ατμού. Ο καταλύτης 5% Ru/MgO/Al2O3 δοκιμάστηκε και υπό συνθήκες αναμόρφωσης του υδατικού κλάσματος του βιοελαίου, και μάλιστα χρησιμοποιήθηκαν δομημένα υποστρώματα, όπως πελλέτες, κεραμικοί μονόλιθοι ή σπόγγοι, έτσι ώστε να αποτελέσματα των συγκεκριμένων πειραμάτων να έχουν άμεση εφαρμογή. Βρέθηκε ότι όλες οι διαφορετικές δομές παρουσιάζουν πολύ καλή ενεργότητα, μετατρέποντας εξ’ ολοκλήρου το βιοέλαιο, καλή εκλεκτικότητα προς παραγωγή υδρογόνου και σταθερή λειτουργία σε σχέση με το χρόνο αντίδρασης. Ωστόσο, ο καταλύτης ρουθηνίου σε πελλέτες βρέθηκε να παρουσιάζει την καλύτερη συμπεριφορά από όλους τους υπόλοιπους. Οι αντιδράσεις αναμόρφωσης και, επομένως, η παραγωγή υδρογόνου ευνοούνται σε υψηλές θερμοκρασίες και μικρές ταχύτητες χώρου. Η εναπόθεση του άνθρακα αποτελεί ένα από τα σημαντικότερα προβλήματα σε αυτού του είδους τις διεργασίες. Μόνο ένα μικρό μέρος του παρεχόμενου άνθρακα εναποτίθεται στην καταλυτική επιφάνεια, κυρίως στη μορφή CHx. Ωστόσο, ο σχηματισμός ανθρακικών εναποθέσεων είναι αρκετά πιο έντονος στα τοιχώματα του αντιδραστήρα πάνω από την καταλυτική κλίνη, λόγω του ομογενούς πολυμερισμού των ασταθών συστατικών του βιοελαίου. Τέλος, διάφοροι καταλύτες ευγενών μετάλλων (Pt, Pd, Ru, Rh) υποστηριζόμενοι σε φορέα Al2O3¬ δοκιμάσθηκαν ως προς την καταλυτική τους ενεργότητα και εκλεκτικότητα υπό συνθήκες αναμόρφωσης αιθανόλης με ατμό, στο θερμοκρασιακό εύρος των 280-450 0C. Βρέθηκε ότι ο Pt και το Pd είναι τα πιο ενεργά από τα μέταλλα που εξετάστηκαν. Η διερεύνηση της επίδρασης του φορέα στην καταλυτική ενεργότητα και εκλεκτικότητα έγινε σε καταλύτες Pt διεσπαρμένους σε διάφορους φορείς μεταλλικών οξειδίων (Al2O3, CeO2, ZrO2, YSZ). Οι συγκεκριμένοι καταλύτες δοκιμάστηκαν και για την σταθερότητά τους συναρτήσει του χρόνου αντίδρασης. Ο καταλύτης Pt/Al2O3 βρέθηκε να παρουσιάζει την μεγαλύτερη ενεργότητα και την υψηλότερη εκλεκτικότητα, υπό συνθήκες αντίδρασης, αλλά και πολύ σταθερή λειτουργία με το χρόνο αντίδρασης. Τέλος, παρουσία του συγκεκριμένου καταλύτη διερευνήθηκε το δίκτυο αντιδράσεων που λαμβάνει χώρα σε συνθήκες αναμόρφωσης της αιθανόλης. / In the present study is investigated the process of steam reforming reaction of bio-fuels, such as bio-oil and bio-ethanol, for the production of a gas stream rich to hydrogen, in order to feed fuel cells. Hydrogen, in combination with fuel cells, is being considered as an environmentally friendly source of energy for automotive as well as stationary applications. Hydrogen has the significant advantage of producing no air or other pollutants in its transformation to energy, while fuel cells, which operate primarily on hydrogen, offer enhanced efficiency in power generation. However, real environmental benefits are linked to the ability to produce hydrogen from renewable sources with no net production of greenhouse gasses. A viable renewable source, gaining attention in recent years, is bio-fuels. Bio-oil and bio-ethanol are bio-fuels because they are originated from biomass treatment, and, in particular, via the fast pyrolysis and the fermentation of biomass, respectively. Their steam reforming reaction is entirely feasible from the thermodynamic point of view, while the efficiency of such process in hydrogen production is significantly high. Thermodynamically the reaction of steam reforming is favored at high temperatures and low pressures. Due to the complexity of bio-oil, which is consisted of hundreds of organics oxygenates, model compounds representatives of bio-oil, are initially used. Acetic acid was chosen as a model compound, because it is present in significant amounts in bio-oil (~10%). A variety of supported metal catalysts were tested under conditions of steam reforming of acetic acid. The influence of several parameters on catalytic activity and selectivity were examined, including catalyst composition, i.e. nature of the metal and the carrier, reaction temperature and time on stream. The metallic phase of such catalysts was comprised of various metals, such as Pt, Pd, Rh, Ru and Ni, which were supported on metal oxides carriers, such as Al2O3, La2O3/Al2O3, MgO/Al2O3 and CeO2/Al2O3. It was found that Ni-based and Ru-based catalysts present high activity and selectivity toward hydrogen production. Ru catalysts supported on La2O3/Al2O3 and MgO/Al2O3 carriers, showed good long term stability as a function of time on stream. However, Ni catalysts were not as stable as Ru catalysts. The amount of carbon deposited on each catalyst was estimated, and it was found that it depends strongly on the nature of the catalyst. The reaction network under conditions of steam reforming of acetic acid was investigated over Al2O3 and La2O3, and Ni catalyst supported on La2O3/Al2O¬3 carrier, employing transient and steady-state techniques. It was found that acetic acid interacts strongly with the Al¬2O3 carrier and less strongly with La2O3. Decomposition reactions as well as the ketonization reaction take place, especially at intermediate temperatures. Reforming reactions and the WGS reaction occur at higher temperatures. In the presence of Ni, catalytic activity is shifted toward lower temperatures. Nickel promotes steam reforming reactions and retards the rate of carbon deposition onto the catalyst surface. It was also found that carbon formation is affected by reaction temperature, the HAc/H2O ratio, and catalyst composition. Carbon deposition is favoured at low reaction temperatures, at more acidic carriers and at high HAc/H2O ratio. Transient experiments were also conducted for the Ru catalysts supported on Al2O3 and MgO/Al2O3 carriers. It was found that, in this case as well, the ketonization reaction firstly, and decomposition reaction of acetic acid secondly, favoured at intermediate temperatures. In the presence of Ru, catalytic activity is shifted towards lower temperatures and hydrogen production occurs at high rates. Ru catalysts promote the steam reforming reaction and retard the rate of carbon deposition onto the catalytic surface. Also, the role of MgO in catalyst formulation was elucidated. It has been found that the solid-state reaction of alumina with magnesium oxide is complete, forming magnesium aluminate spinel. The enhanced activity of the Ru/MgO/Al2O3 catalyst, as compared to the Ru/Al2O3 one, seems to be associated with the fact that the magnesium aluminate spinel offers enhanced O and/or –OH anion spillover from the carrier onto the metal particles, reduced acidity as compared to the alumina carrier, as well as enhanced ability for H2O adsorption. A series of Ru/MgO/Al2O3 catalysts supported on cordierite monoliths, ceramic foams and γ-Al2O3 pellets were prepared and tested for the production of hydrogen by catalytic steam reforming of the aqueous fraction of bio-oil. All different structural forms of the catalyst exhibited satisfactory activity, converting completely the bio-oil, good selectivity toward hydrogen and satisfactory stability with time on stream. However, the catalyst supported on pellets exhibited the best catalytic performance, among all catalysts investigated. Reforming reactions, and thus hydrogen production, are favoured at high temperatures and low space velocities. Coking is one of the most significant problems encountered in these processes. It was found that only a small part of the incoming carbon is deposited on the catalyst surface, which is mainly present as CHx. However, coke deposition is more intense on the reactor wall above the catalytic bed, due to homogeneous polymerization of unstable ingredients of bio-oil. Finally, a variety a noble metal catalysts (Pt, Pd, Ru, Rh), supported on the Al2O3 carrier were tested with respect to their catalytic activity and selectivity under conditions of steam reforming of ethanol, in the temperature range of 280-450 0C. It was found that Pt and Pd are the most active metal among all catalysts tested. The effect of the carrier nature was investigated for Pt catalysts supported on a variety of metal oxide carriers, such as Al2O3, CeO2, ZrO2 and YSZ. These catalysts were also tested for their stability as a function of time on stream. The Pt/Al2O3 catalyst presents the highest activity and selectivity among all catalysts tested, as well as very stable performance with time on stream. Finally, the reaction network under conditions of ethanol reforming, in the presence of the specific catalyst, was investigated.

Αναμόρφωση με ατμό

Παραγωγή υδρογόνου

Βιοέλαιο

Βιοαιθανόλη

Καταλύτες Ρουθηνίου

Καταλύτες Νικελίου

665.776

Steam reforming

Hydrogen production

Biooil

Bioethanol

Ruthenium catalysts

Nickel catalysts

Preparação e caracterização de catalisadores de níquel suportado em óxido de zircônio e aluminio

Berrocal, Guillermo José Paternina

January 2005

Submitted by Edileide Reis (leyde-landy@hotmail.com) on 2013-04-23T11:48:39Z No. of bitstreams: 5 Guilhermo Berrocal 5.pdf: 441982 bytes, checksum: ed6d9be182498c6b4db2d0c4a32f7ac8 (MD5) Guilhermo Berrocal 4.pdf: 1385591 bytes, checksum: c4e7c73fa8dc1eec5a3eb4d438068c56 (MD5) Guilhermo Berrocal 3.pdf: 1956923 bytes, checksum: f8dc8503637b206d198b9966a177a091 (MD5) Guilhermo Berrocal 2.pdf: 289780 bytes, checksum: 3fc530194e3c8918ac11f9c2ccdabc15 (MD5) Guilhermo Berrocal 1.pdf: 340675 bytes, checksum: 7e5ee755b290eae4c9ff083197916037 (MD5) / Made available in DSpace on 2013-04-23T11:48:39Z (GMT). No. of bitstreams: 5 Guilhermo Berrocal 5.pdf: 441982 bytes, checksum: ed6d9be182498c6b4db2d0c4a32f7ac8 (MD5) Guilhermo Berrocal 4.pdf: 1385591 bytes, checksum: c4e7c73fa8dc1eec5a3eb4d438068c56 (MD5) Guilhermo Berrocal 3.pdf: 1956923 bytes, checksum: f8dc8503637b206d198b9966a177a091 (MD5) Guilhermo Berrocal 2.pdf: 289780 bytes, checksum: 3fc530194e3c8918ac11f9c2ccdabc15 (MD5) Guilhermo Berrocal 1.pdf: 340675 bytes, checksum: 7e5ee755b290eae4c9ff083197916037 (MD5) Previous issue date: 2005 / Níquel suportado em alumina tem sido extensivamente usado para catalisar a reforma a vapor do metano, devido ao seu baixo custo, quando comparado a outros catalisadores, à base de metais nobres. Entretanto, ele não é estável durante a reação principalmente devido à transição de fase e à sinterização do suporte. Isto requer o desenvolvimento de novos catalisadores. Uma opção atrativa seria usar suportes baseados em zircônia, que possui diversas vantagens, tais como estabilidade térmica, dureza e propriedades anfotériças, mas esse sólido possui baixa área superficial específica, quando comparado a suportes catalíticos convencionais. Uma provável solução para esse problema é combinar as propriedades da alumina e da zircônia. Com este objetivo foi estudada, neste trabalho, a preparação e caracterização de catalisadores de níquel suportado em zircônia e alumina. Os suportes foram preparados por métodos de precipitação à temperatura ambiente, a partir de soluções aquosas de oxicloreto de zircônio e de nitrato de alumínio, seguido de calcinação a 500 oC. Foram obtidos sólidos com razões molares Zr/Al (molar) = 10; 5; 2; 1; 0,5; 0,2 e 0.1, além de alumina e zircônia puras. Os catalisadores foram preparados por métodos de impregnação de soluções de nitrato de níquel, seguido de calcinação a 500 oC. As amostras foram caracterizadas por energia dispersiva de raios X, termogravimetria, análise térmica diferencial, espectroscopia no infravermelho, com transformadas de Fourier, difração de raios X, redução termoprogramada, medidas de área superficial específica e porosidade e espectroscopia fotoeletrônica de raios X. O efeito da temperatura sobre a cristalização dos suportes foi estudada "in situ" por difração de raios X, usando uma câmara de aquecimento. Observou-se a presença das fases tetragonal e monoclínica na zircônia pura e g-Al2O3 na alumina pura. A adição de pequenas quantidades de alumínio estabilizou a fase tetragonal da zircônia, enquanto quantidades mais elevadas de alumínio levaram à produção de sólidos mal cristalizados. As amostras ricas em alumínio (Zr/Al= 0,1; 0,2 e 0,5) também produziram g-Al2O3. A altas temperaturas, os sólidos mal cristalizados formaram aluminato de níquel. A área superficial específica aumentou com a adição de alumínio, o que foi atribuído à presença desse metal na superfície do sólido, onde ele atua como espaçador. A amostra pobre em alumínio (Zr/Al= 0,1) mostrou a área superficial específica mais elevada. Entretanto, a área superficial específica decresceu devido à adição de níquel, provavelmente devido ao bloqueio de alguns poros por esse metal. As amostras apresentaram poros com diferentes formas e tamanhos e produziram isotermas dos Tipos II e III com "loops" de histerese, típicas de materiais mesoporosos. A adição de alumínio também afetou a redução de níquel, tornando esse processo mais difícil; este efeito aumentou com a quantidade de níquel nos sólidos. Entre as amostras à base de alumínio e zircônio, o sólido com quantidades iguais desses metais (Zr/Al (molar)= 1) apresentou o teor mais elevado de níquel na superfície. Ele apresenta área superficial específica elevada e pode ser facilmente reduzido, permitindo a formação da fase ativa do catalisador, na reforma a vapor do metano. Portanto, esse sólido é o catalisador mais promissor para essa reação. / Salvador

Catalisador de níquel

Reforma a vapor de metano

Óxido de zircônio e alumínio

Óxido de zircônio

Físico-química

System ZrO2-Al2O3

Zirconia

Methane steam reforming

Nickel catalysts

Analysis of Deactivation Mechanism on a Multi-Component Sulfur-Tolerant Steam Reforming Catalyst

Lakhapatri, Satish L.

03 September 2010

No description available.

Chemical Engineering

Chemistry

Energy

Engineering

Environmental Engineering

Environmental Science

Steam reforming

Logistic fuels

Catalyst deactivation

Carbon deposition

Sulfur poisoning

Nickel catalysts

Carbon Nanotubes: Chemical Vapor Deposition Synthesis and Application in Electrochemical Double Layer Supercapacitors

Turano, Stephan Parker

08 March 2005

Carbon nanotubes (CNTs) have become a popular area of materials science research due to their outstanding material properties coupled with their small size. CNTs are expected to be included in a wide variety of applications and devices in the near future. Among these devices which are nearing mass production are electrochemical double layer (ECDL) supercapacitors. The current methods to produce CNTs are numerous, with each synthesis variable resulting in changes in the physical properties of the CNT. A wide array of studies have focused on the effects of specific synthesis conditions. This research expands on earlier work done using bulk nickel catalyst, alumina supported iron catalyst, and standard chemical vapor deposition (CVD) synthesis methods. This work also investigates the effect of an applied voltage to the CVD chamber during synthesis on the physical nature of the CNTs produced. In addition, the work analyzes a novel nickel catalyst system, and the CNTs produced using this catalyst. The results of the effects of synthesis conditions on resultant CNTs are included. Additionally, CNT based ECDL supercapacitors were manufactured and tested. Scanning electron microscope (SEM) analysis reveals that catalyst choice, catalyst thickness, synthesis temperature, and applied voltage have different results on CNT dimensions. Nanotube diameter distribution and average diameter data demonstrate the effect of each synthesis condition. Additionally, the concept of an alignment parameter is introduced in order to quantify the effect of an electric field on CNT alignment. CNT based ECDL supercapacitors testing reveals that CNTs work well as an active material when a higher purity is achieved. The molarity of the electrolyte also has an effect on the performance of CNT based ECDL supercapacitors. On the basis of this research, we conclude that CNT physical dimensions can be moderately controlled based on the choice of synthesis conditions. Also, the novel nickel catalyst system investigated in this research has potential to produce bulk quantities of CNT under specific conditions. Finally, purified CNTs are recommended as a suitable active material for ECDL supercapacitors.

Nanomaterials

Nanotechnology

ECDL

Supercapacitor

CVD

Chemical vapor deposition

CNTs

Carbon nanotubes

Nickel catalysts

Carbon

Chemical vapor deposition Synthesis

Electric double layer

Nanotubes Synthesis

Μελέτη της ρόφησης υδατικών συμπλόκων του νικελίου στην επιφάνεια του οξειδίου του τιτανίου

Σταυρόπουλος, Ιωάννης

15 February 2012

Βασικός στόχος της παρούσας διατριβής είναι η αποσαφήνιση του τρόπου της διεπιφανειακής εναπόθεσης του νικελίου στην επιφάνεια της τιτάνιας, η οποία λαμβάνει χώρα στη διεπιφάνεια “τιτάνιας / ηλεκτρολυτικού διαλύματος”. Ο στόχος αυτός επιτεύχθηκε μέσω μιας κατάλληλης θεωρητικής και υπολογιστικής επεξεργασίας δεδομένων, που προέρχονται από την εφαρμογή ηλεκτροχημικών και φασματοσκοπικών τεχνικών, την εκτέλεση πειραμάτων προσρόφησης, καθώς επίσης και σε ab – initio υπολογισμούς για την εξακρίβωση της δομής των συμπλόκων εσωτερικής σφαίρας τα οποία σχηματίζονται και των συγκεντρώσεών τους στη διεπιφάνεια. Δείγματα βιομηχανικής τιτάνιας (Degussa, P 25) πλούσιας σε ανατάση χρησιμοποιήθηκαν για το σκοπό αυτό. Η μελέτη πραγματοποιήθηκε για μια ευρεία περιοχή παραμέτρων εμποτισμού και πιο συγκεκριμένα τιμές pH, ιονικής ισχύος και συγκέντρωσης του υδατικού συμπλόκου [Ni(H2O)6]2+ στο διάλυμα. Μεταβάλλοντας τις παραμέτρους αυτές ρυθμίστηκε η επιφανειακή συγκέντρωση των ιόντων Ni(II). Χρησιμοποιήθηκε μια πληθώρα μεθοδολογιών στηριγμένες σε δεδομένα εναπόθεσης, μετρήσεις τιμών pH, ποτενσιομετρικές τιτλοδοτήσεις μάζας και πειράματα μικροηλεκτροφόρησης σε συνδυασμό με φασματοσκοπία διάχυτης ανάκλασης (DRS). Ο συνδυασμός όλων των παραπάνω φαίνεται πως υποδεικνύει το σχηματισμό μονοπυρηνικών / ολιγοπυρηνικών συμπλόκων εσωτερικής σφαίρας κατά την εναπόθεση των ιόντων [Ni(H2O)6]2+ στη διεπιφάνεια “τιτάνιας / ηλεκτρολυτικού διαλύματος”. Η μοντελοποίηση της διαδικασίας εναπόθεσης η οποία βασίστηκε στα προαναφερθέντα πειραματικά αποτελέσματα, αποκάλυψε την ακριβή δομή αυτών των επιφανειακών συμπλόκων και κατέστησε δυνατό τον προσδιορισμό της κατανομής των εναποτιθέμενων ειδών και ειδικότερα των σχετικών τους συγκεντρώσεων για διάφορες τιμές της επιφανειακής συγκέντρωσης Ni(II). Στο συμπαγές τμήμα της διεπιφάνειας “τιτάνιας / ηλεκτρολυτικού διαλύματος” σχηματίζονται τρία μονοπυρηνικά σύμπλοκα εσωτερικής σφαίρας: ένα μονο - υποκατεστημένο, δι - υδρολυμένο σύμπλοκο πάνω από τις ακραίες οξο - ομάδες ανταλλάσοντας ένα υδατικό υποκαταστάτη με ένα επιφανειακό άτομο οξυγόνου (διαμόρφωση TiO), ένα δι - υποκατεστημένο, δι - υδρολυμένο σύμπλοκο πάνω από δύο ακραίες γειτονικές οξο - ομάδες ανταλλάσοντας δύο υδατικούς υποκαταστάτες με δύο επιφανειακά άτομα οξυγόνου (διαμόρφωση TiO - TiO) και ένα δι - υποκατεστημένο μη υδρολυμένο σύμπλοκο πάνω από μία ακραία και μία γεφυρωμένη οξο - ομάδα (διαμόρφωση Ti2O - TiO). Επιπρόσθετα, σχηματίζονται ένα διπυρηνικό και ένα τριπυρηνικό σύμπλοκο εσωτερικής σφαίρας κατά την εναπόθεση των ιόντων [Ni(H2O)6]2+ στο συμπαγές τμήμα της διεπιφάνειας “τιτάνιας / ηλεκτρολυτικού διαλύματος”. Στην πρώτη περίπτωση η θέση υποδοχής συμπεριλαμβάνει μία γεφυρωμένη και δύο ακραίες οξο - ομάδες (διαμόρφωση Ti2O-TiO—TiO), ενώ στη δεύτερη περίπτωση δύο γεφυρωμένες και τρεις ακραίες οξο - ομάδες (διαμόρφωση Ti2O-TiO—TiO—TiO-Ti2O). Η διαμόρφωση TiO κυριαρχεί σε όλο το εύρος της περιοχής επιφανειακών συγκεντρώσεων το οποίο μελετήθηκε. Η συνεισφορά των διαμορφώσεων TiO - TiO και Ti2O - TiO είναι επίσης σημαντική σε πολύ χαμηλές τιμές επιφανειακής συγκέντρωσης Ni(II), μειώνεται όμως σε μεγάλο βαθμό καθώς αυτή αυξάνεται. Οι σχετικές επιφανειακές συγκεντρώσεις των διαμορφώσεων Ti2O-TiO--TiO και Ti2O-TiO—TiO--TiO-Ti2O αρχικά αυξάνουν με την επιφανειακή συγκέντρωση Ni(II) και μετά μένουν πρακτικά σταθερές. Η προαναφερθείσα κατανομή των εναποτιθέμενων ειδών στη διεπιφάνεια εξηγήθηκε με τη χρήση στερεοχημικών όρων. Επιπρόσθετα, η δομή των επιφανειακών συμπλόκων εσωτερικής σφαίρας και η κατανομή αυτή είναι σε γενική συμφωνία με εκείνες οι οποίες προβλέφθηκαν με την εκτέλεση ημιεμπειρικών κβαντομηχανικών υπολογισμών για την εναπόθεση του Ni στο TiO2. Το μοντέλο εναπόθεσης το οποίο αναπτύχθηκε περιέγραψε πολύ καλά τις adsorption edges, τις τιτλοδοτήσεις “πρωτονίου - ιόντος” και τις ισόθερμες εναπόθεσης, ενισχύοντας επιπλέον την αξιοπιστία και ορθότητά του. / The main goal of this work is the elucidation of the mode of interfacial deposition of nickel on the surface of titania, which takes place in the “titania / electrolytic solution” interface. This goal was achieved through the use of several methodologies combined with spectroscopic techniques, as well as ab – initio calculations in order to determine the structure of the inner sphere complexes formed as well as their relative interfacial concentrations. Samples of titania (Degussa, P 25) rich in anatase were used for this purpose. The study was performed over a quite wide range of impregnation parameters namely pH, ionic strength and concentration of the [Ni(H2O)6]2+ aqua complex in the solution. By changing these parameters, the Ni(II) surface concentration was regulated. Several methodologies based on deposition data, pH measurements, potentiometric mass titrations and microelectrophoresis have been used in conjunction with diffuse reflectance spectroscopy. These suggested the formation of mono - nuclear / oligo - nuclear inner sphere complexes upon deposition of the [Ni(H2O)6]+2 ions at the “titania / electrolytic solution” interface. The modelling of the deposition process based on the aforementioned experimental results revealed the exact structure of these surface complexes and allowed the determination of their relative concentrations at various values of Ni(II) surface concentration (interfacial speciation). Three mono-nuclear inner sphere complexes are formed at the compact layer of the “titania / electolytic solution” interface; one mono - substituted, di - hydrolyzed complex above the terminal oxo - groups by exchanging one water ligand with a surface oxygen atom (TiO configuration), a di - substituted, di - hydrolyzed complex above two terminal adjacent oxo - groups by exchanging two water ligands with the two surface oxygen atoms (TiO-TiO configuration) and one di - substituted, non - hydrolyzed complex above one terminal and one bridging adjacent oxo - groups ( Ti2O-TiO configuration). One binuclear and one three - nuclear complex are formed, in addition, at the compact layer. In the first case the receptor site involves one bridging and two terminal oxo- groups (Ti2O-TiO--TiO configuration) whereas in the second case the receptor site involves two bridging and three terminal oxo - groups (Ti2O-TiO--TiO--TiO-Ti2O configuration). The TiO configuration predominates in the whole range of the surface concentration studied. The contribution of the TiO-TiO and Ti2O-TiO configurations is also important at very low Ni(II) surface concentration, but this contribution is rapidly decreased as the Ni(II) surface concentration increases. The relative surface concentrations of the Ti2O-TiO--TiO and Ti2O-TiO--TiO--TiO-Ti2O configurations initially increase with the Ni(II) surface concentration and then remain practically constant. The aforementioned interfacial speciation was explained in stereochemical terms. Moreover, the structure of the inner sphere surface complexes and the interfacial speciation are in general agreement with those predicted by performing semi-empirical quantum chemical calculations of the deposition process. The deposition model developed has described the ‘adsorption edges’, the ‘proton–ion titration curves’ and the deposition isotherms well, further corroborating its validity.

Καταλύτες νικελίου

Οξείδιο του τιτανίου

Προσρόφηση

541.33

Nickel catalysts

Titanium oxide

Adsorption

Solid-liquid interface

Inner sphere complex

Supported catalysts

Surface and interface science