Tesis sobre el tema "Overall alkaline water splitting"
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Jiang, Tao. "Development of Alkaline Electrolyzer Electrodes and Their Characterization in Overall Water Splitting". Thesis, Bourgogne Franche-Comté, 2020. http://www.theses.fr/2020UBFCA006.
Texto completoSplitting water into hydrogen and oxygen by electrolysis using electricity from intermittent ocean current, wind, or solar energies is one of the easiest and cleanest routes for high-purity hydrogen production and an effective way to store the excess electrical power without leaving any carbon footprints. The key dilemma for efficient large-scale production of hydrogen by splitting of water via the hydrogen and oxygen evolution reactions is the high overpotential required, especially for the oxygen evolution reaction. Hence, engineering highly active and stable earth-abundant oxygen evolution electrocatalysts with three-dimensional hierarchical porous architecture via facile, effective and commercial means is the main objective of the present PhD study. Finally, we developed two kinds of good performance oxygen evolution electrocatalysts through two different way combined with in situ electrochemical activation.For the first oxygen evolution electrocatalyst, we report a codoped nickel foam by nickel crystals, tricobalt tetroxide nanoparticles, graphene oxide nanosheets, and in situ generated nickel hydroxide and nickel oxyhydroxide nanoflakes via facile electrolytic codeposition in combination with in situ electrochemical activation as a promising electrocatalyst for oxygen evolution reaction. Notably, this hybrid catalyst shows good electrocatalytic performance, which is comparable to the state-of-the-art noble catalysts. The hybrid catalyst as an electrocatalytically-active and robust oxygen evolution electrocatalyst also exhibits strong long-term electrochemical durability. Such a remarkable performance can be benefiting from the introduced active materials deposited on nickel foam, in situ generated nickel oxyhydroxide nanoflakes and their synergistic effects. It could potentially be implemented in large-scale water electrolysis systems.For the second oxygen evolution electrocatalyst, a facile and efficient means of combining high-velocity oxy-fuel spraying followed by chemical activation, and in situ electrochemical activation based on oxygen evolution reaction has been developed to obtain a promising self-supported oxygen evolution electrocatalyst with lattice-distorted Jamborite nanosheets in situ generated on the three-dimensional hierarchical porous framework. The catalyst developed in this work exhibits not only exceptionally low overpotential and Tafel slope, but also remarkable stability. Such a remarkable feature of this catalyst lies in the synergistic effect of the high intrinsic activity arising from the lattice-dislocated Jamborite nanosheets as the highly active substance, and the accelerated electron/ion transport associated with the hierarchical porous architecture. Notably, this novel methodology has the potential to produce large-size-electrode for alkaline water electrolyzer, which can provide new dimensions in design of highly active and stable self-supported electrocatalysts.Furthermore, we have also initially developed good hydrogen evolution electrocatalysts upon in situ electrochemical activation, coupled with the obtained superior oxygen evolution electrocatalysts forming two-electrode configurations, respectively, both of which rivalled the integrated state-of-the-art ruthenium dioxide-platinum electrode in alkaline overall water splitting.In summary, a methodology of fabricating easy-to-commercial, high performance catalytic electrodes by combining general coating processes with in situ electrochemical activation has been realized and well developed. The in situ electrochemical activation mentioned above is a dynamic self-optimization behavior which is facile, flexible, effective and eco-friendly, as a strategy of fabricating self-supported electrodes for efficient and durable overall water splitting. We hope our work can promote advanced development toward large-scale hydrogen production using excess electrical power whenever and wherever available
Sommers, Jacob. "Towards Photocatalytic Overall Water Splitting via Small Organic Shuttles". Thesis, Université d'Ottawa / University of Ottawa, 2016. http://hdl.handle.net/10393/34607.
Texto completoSong, Yang. "Design of metal silicide nanoparticles in molten salts : electrocatalytic and magnetic properties". Electronic Thesis or Diss., Sorbonne université, 2021. https://accesdistant.sorbonne-universite.fr/login?url=https://theses-intra.sorbonne-universite.fr/2021SORUS498.pdf.
Texto completoTransition metal silicides are a family of intermetallic compounds, which have been widely studied as functional materials in integrated circuits, thermoelectricity, superconductivity, magnetism and heterogeneous catalysis. Nanostructuration offers the opportunity to extend the frontier of silicon-based materials science with novel phases and diverse properties. However, building transition metal silicides encompassing relatively high energy bonds usually requires high temperatures, which are not conducive for nanomaterial design and not compatible with the traditional colloidal synthesis methods. In this thesis, molten salts syntheses based on element insertion into nanoparticles are developed. Transition metal silicide nanoparticles (M-Si, M=Ni, Fe, NiFe, Co) and a ternary nickel silicophosphide are crystallized in high temperature inorganic solvents, where a diluted and carbon-free environment is provided. The obtained silicide nanoparticles are investigated in electrocatalysis of alkaline water oxidation and magnetism. NiFe silicides demonstrate outstanding activity and stability arising from an original in situ generated core-shell-shell structure, while defect-rich CoSi nanoparticles show an unusual surface related ferromagnetism. Moreover, the study of silicophosphide nanoparticles provides an insight in multinary material design in molten salts and the role of nonmetal elements in overall alkaline water splitting electrocatalysis
Liu, Meng <1991>. "Nanocarbon-Supported Electrocatalysts for the Alkaline Water Splitting and Fuel Cells". Doctoral thesis, Alma Mater Studiorum - Università di Bologna, 2021. http://amsdottorato.unibo.it/9544/1/Liu_Meng_thesis.pdf.
Texto completoFan, Kaicai. "Development of High Performance Electrocatalyst for Water Splitting Application". Thesis, Griffith University, 2018. http://hdl.handle.net/10072/382229.
Texto completoThesis (PhD Doctorate)
Doctor of Philosophy (PhD)
School of Environment and Sc
Science, Environment, Engineering and Technology
Full Text
Zhang, Jian, Tao Wang, Darius Pohl, Bernd Rellinghaus, Renhao Dong, Shaohua Liu, Xiaodong Zhuang y Xinliang Feng. "Interface Engineering of MoS2/Ni3S2 Heterostructures for Highly Enhanced Electrochemical Overall Water Splitting Activity". Saechsische Landesbibliothek- Staats- und Universitaetsbibliothek Dresden, 2018. http://nbn-resolving.de/urn:nbn:de:bsz:14-qucosa-235457.
Texto completoPark, Kyoung-Won. "Solar-driven overall water splitting on CoO nanoparticles : first-principles density functional theory studies". Thesis, Massachusetts Institute of Technology, 2018. http://hdl.handle.net/1721.1/117802.
Texto completoThis electronic version was submitted by the student author. The certified thesis is available in the Institute Archives and Special Collections.
Cataloged student-submitted from PDF version of thesis.
Includes bibliographical references (pages 143-157).
Photoelectrochemical (PEC) water splitting has been suggested as a promising techinique for large-scale hydrogen fuel production. In particular, spontaneous photocatalytic overall water splitting on self-standing particles in water without external driving potential has been highlighted as a clean and economical energy generation method for the future. Among various photocatalytic materials, some cobalt-based materials including CoP, Co₂P, Co(OH)₂, CoO, have attained major interest because they exhibit improved catalytic activity for hydrogen evolution in the form of nanoparticles, unlike most cobalt-based materials which have been assessed as water oxidizing catalysts in the past decade. CoO nanoparticles have been observed to photocatalytically split water into H₂ and O₂ at room temperature without an externally applied potential or co-catalyst, with high photo-catalytic efficiency (solar-to-hydrogen efficiency of ~5%) which hits the record among single-material self-standing photocatalysts. The photocatalytic activity of CoO nanoparticles was experimentally shown to stem from the optimal conduction and valence band edge positions (Ec and Ev) relative to water reduction and oxidation potential levels (H+/H₂ and H₂O/O₂), such that the Ec and EV span the water redox potentials. The overall water splitting is not expected from CoO micropowder or bulk CoO because they have band edges far below the H+/H2 level, which are not optimal for overall water splitting. However, the origin of the shift in the band edges due to decrease in particle size (from bulk or micropowder to nanoparticle) was unknown. Moreover, the mechanism by which H₂ and O₂ simultaneously and spontaneously evolve on the nanoparticles, as well as how the CoO nanoparticles could exhibit a high photocatalytic efficiency even without a co-catalyst or an external driving potential have remained unanswered. In this work, we use first-principles density functional theory (DFT) calculations to explore thermodynamically stable surface configurations of CoO in an aqueous environment in which photocatalytic water splitting occurs. We also calculate the Ec and Ev of CoO surfaces relative to water redox potentials, showing that the band edge positions are sensitive to surface chemistry which is determined by surface orientation, adsorbates, and stoichiometry, and thus growth conditions and operating environment. In particular, we predict that CoO nanoparticles have fully hydroxylated CoO(111) facets (OH*-CoO(111)), with band edges spanning the water redox potentials, while larger CoO particles (such as CoO micropowders) have a full monolayer of hydrogen on the CoO(111) facets, with a band alignment that favors water oxidation but not water reduction. From these calculations, we demonstrate that explicit inclusion of liquid water is crucial for accurately predicting the band edge positions, and thus photocatalytic behavior of CoO in an aqueous solution. In order to find the origin of the high efficiency and spontaneous overall water splitting without an external bias or a co-catalyst, we also elucidate the mechanisms for charge separation and H₂ and O₂ evolution on CoO nanoparticles under illumination in an aqueous solution. We demonstrate that electrons are driven to CoO(100) facets and holes are driven to OH*-CoO(111) facets as a result of a built-in potential arising from the very different potential levels of the two facets. We show that H₂ evolution preferentially occurs on the CoO(100) facets, while O2 evolves on the OH*-CoO(111) surfaces, based on our new criteria. Importantly, we suggest that the conventional criterion for determining the feasibility of H₂ or O₂ generation from water splitting - i.e., EC < H+/H₂ level or Ev > H₂O/O₂ level - is insufficient. Instead, we suggest that a more appropriate set of criteria is whether the photo-excited electrons and holes have sufficient energy to overcome the kinetic barrier for the H₂ and O₂ evolution reaction, respectively, on the relevant surface facet. This work explains why and how photocatalytic overall water splitting has been observed only on CoO nanoparticles. Our understanding of the overall water splitting mechanism on CoO nanoparticles provides a general explanation of experimentally observed overall water splitting phenomena on a variety of self-standing photocatalysts as well as a new approach for screening novel photocatalytic materials for efficient water splitting and other reactions.
by Kyoung-Won Park.
Ph. D.
Adeli, Koudehi Babak. "Solar hydrogen generation through overall water splitting on gallium-zinc oxynitride visible-light activated photocatalyst". Thesis, University of British Columbia, 2017. http://hdl.handle.net/2429/60303.
Texto completoChemical and Biological Engineering, Department of
Graduate
Li, Junwei. "Investigation of Structural-Catalytic Relationship of Mixed-Metal Layered Oxide Materials for Photocatalytic Overall Water Splitting". Thesis, The University of Sydney, 2022. https://hdl.handle.net/2123/29385.
Texto completoBerto, Tobias [Verfasser], Johannes A. [Akademischer Betreuer] [Gutachter] Lercher y Tom [Gutachter] Nilges. "Elucidation of reaction pathways of the photoreforming and overall water splitting reaction over precious metal decorated semiconductors / Tobias Berto ; Gutachter: Johannes A. Lercher, Tom Nilges ; Betreuer: Johannes A. Lercher". München : Universitätsbibliothek der TU München, 2016. http://d-nb.info/1123210861/34.
Texto completoRodene, Dylan D. "Engineering of Earth-Abundant Electrochemical Catalysts". VCU Scholars Compass, 2019. https://scholarscompass.vcu.edu/etd/6106.
Texto completoLin, Yu-Cheng y 林于程. "Z-scheme overall water splitting over K4Nb6O17 photocatalyst". Thesis, 2013. http://ndltd.ncl.edu.tw/handle/77657577587157549572.
Texto completo國立東華大學
材料科學與工程學系
101
In this study, we combine H2 evolution photocatalyst with O2 evolution photocatalyst, and use an aqueous NaI solution as I-/IO3- shuttle redox mediator in Z-scheme photocatalysis system for water splitting. We use solid state reaction to prepare H2 evolution photocatalyst, K4Nb6O17, and loading Rh as cocatalyst to improve hydrogen production. When the amount of loading Rh up to 1.5wt%, we get H2 evolution rate about 24mmol h-1 g-1 was higher than K4Nb6O17(337μmoleg-1h-1) as prepared. Then, we use exfoliation method to prepare our nanosheets photocatalyst, NS-K4Nb6O17, and loading Rh as cocatalyst, and exhibited a highest H2 evolution rate about 71 mmoleg-1h-1 when 1.5wt%Rh was loading. O2 evolution photocatalyst use WO3 loading 0.5wt%Pt as cocatalyst. The rate of H2 evolution and O2 evolution under UV irradiation significantly changed with the concentration of NaI, and the pH value of the reactant solution. The H2 and O2 production rate of K4Nb6O17/WO3-0.5wt%Pt Z-scheme photocatalysis system was 263μmol h-1 g-1 and 126μmol h-1 g-1, respectively. The optimal NaI concentration of the reactant solution 4mM at pH = 11. The H2 evolution and O2 evolution rate of K4Nb6O17/WO3-0.5wt%Pt Z-scheme photocatalysis system were enhanced by loading Rh nanoparticles as cocatalyst(H2:533μmoleg-1h-1,O2:259μmoleg-1h-1). The Z-scheme photocatalysis system with NS-K4Nb6O17 -1.5 wt%Rh/WO3-0.5wt%Pt photocatalysts exhibited a highest photoactivity with a H2 evolution rate of 1329μmol h-1 g-1 and a O2 evolution rate of 341μmol h-1 g-1.
Wang, Hsuan-Chi y 王宣期. "Overall water splitting Catalyzed by Dinitrosyl Iron Complex". Thesis, 2017. http://ndltd.ncl.edu.tw/handle/6kcgkb.
Texto completoDeng, Xiaohui. "Photocatalytic and Photoelectrochemical Water Splitting by Inorganic Materials". Thesis, 2012. http://hdl.handle.net/10754/255086.
Texto completoGunawanIp y 葉燊寶. "Investigations on GaN-ZnO and Diode-type Photocatalysts for Overall Water Splitting". Thesis, 2012. http://ndltd.ncl.edu.tw/handle/32111502132288925839.
Texto completo國立成功大學
化學工程學系碩博士班
100
Developing a new kind of visible light water splitting photocatalyst is a new challenge for the development of renewable energy utilization by employing water splitting process. GaN-ZnO solid solution photocatalyst has been known as a visible light photocatalyst with suitable band position for water splitting reaction. The addition of Zn into Ga2O3 as a starting material for GaN-ZnO is considered as a new way to improve the photocatalytic activity for GaN-ZnO. The main purpose for loading Zn into Ga2O3 is to prevent the photocatalyst to be fully converted into GaN at niridation process. This method has been proved in this experiment to be successful for increasing Zn/Ga ratio in final product and also increasing the H2 and O2 gas evolution rate of GaN-ZnO photocatalyst. GaN-ZnO photocatalyst from 2% Zn loaded Ga2O3 shows higher H2 (181.21 micromol/h) and O2 evolution (49.11 micromol/h) compared with the same photocatalyst from commercial Ga2O3. In the second part of this study, junction photocatalyst consists of p-type photocatalyst, n-type photocatalyst, and noble metal in between was made. Two different junction photocatalysts have been made which are Cu2O/Au/WO3 and Ag2O/Ag/WO3. For Cu2O/Au/WO3 photocatalyst, Cu2O photodeposition pH is varied to get the junction photocatalyst with the best activity. The result shows that Cu2O/Au/WO3 photocatalyst with the best performance is the photocatalyst which was synthesized at pH = 8.2. Too low photodeposition pH will make Cu2O can’t be well deposited. On the contrary, too high photodeposition pH will cause some of the WO3 to be dissolved and interfere with photodeposition process. For another junction photocatalyst, Ag2O/Ag/WO3, the amount of total Ag loaded into WO3 is varied. The result shows that Ag2O/Ag/WO3 junction photocatalyst with the ratio of Ag to WO3 = 1 : 2 gives the highest activity, even with the termination of O2 evolution after 20 hours of irradiation. Addition of more Ag into WO3 caused Ag overloading which make the photocatalyst quickly covered with Ag and lost its activity. Meanwhile, termination of O2 evolution could be caused by redeposition of Ag which covers WO3 active site.
Chiang, Yung-Hsiang y 江永翔. "Preparation of BiVO4 photocatalyst for Oxygen production by Z-scheme overall water splitting". Thesis, 2016. http://ndltd.ncl.edu.tw/handle/33025750420041229724.
Texto completo國立東華大學
材料科學與工程學系
104
In this study , we use microwave–assisted to prepare O2 evolution photocatalyst, BiVO4. H2 evolution photocalyst use SSK4Nb6O17. The characterization of as-prepared BiVO4 was carried out by X-ray diffraction (XRD), Field Emission Scanning electron microscope (FE-SEM), ultraviolet-visible analyzer(UV-vis) and Surface Area & Mesopore Analyzer(BET) . In the process of photocatalyst synthesis, regulation of nitric acid concentration, temperature, and time as a different synthetic condition. Synthesis of time increases by the cubic morphology BiVO4 photocatalyst massive agglomeration into spherical structure and increasing the particle size. Synthesis of nitric acid concentration increased BiVO4 photocatalyst particles produced spherical agglomeration structure. Synthesis reaction temperature is increased to BiVO4 photocatalyst particle morphology little effect. With the synthesis reaction time stretched BiVO4 photocatalyst reduce the band gap. Synthesis of nitric acid concentration and temperature for BiVO4 photocatalyst band gap has little effect. Preparation impregnated with Pt/BiVO4 photocatalyst, Pt average particle size 17nm, evenly spread over the surface of the BiVO4 photocatalyst. Pt/BiVO4 photocatalyst was prepared by photodeposition method. Pt particles selectively deposited on {010} planes BiVO4 photocatalyst. Pt/BiVO4 photocatalyst optical absorption edge will move longer wavelength . Synthesis of nitric acid concentration increased, BiVO4 photocatalytic reaction rate decreases oxygen production. Synthesis of reaction temperature increases, BiVO4 photocatalytic reaction rate increased oxygen production. Synthesis of reaction temperature BiVO4 photocatalytic reaction rate on oxygen production is very important. The BiVO4(0.5M 180℃1hr) photocatalyst has the best photocatalytic reaction rate of oxygen production in AgNO3 aqueous solution. A O2 evolution rate of 2622 μmoleg-1h-1. Pt photodeposited BiVO4 photocatalyst was better than pure BiVO4 photocatalyst, the photocatalytic reaction rate of oxygen production was up 2 times in 5mM NaIO3 aqueous solution. Z-scheme system consist to hydrogen production catalyst (0.5wt%Rh/SSK4Nb6O17) and oxygen production catalyst(Pt/BiVO4). We found the Z-scheme photocatalysis system with 0.5wt%Pt-BiVO4-0.5wt%Rh/SSK4Nb6O17 photocatalysts exhibited a highest photoactivity with a H2 evolution rate of 348 μmole g-1 h-1 and a O2 evolution rate of 172 μmole g-1 h-1.
Peng, Chun-Kuo y 彭俊國. "The Study on Copper-Based Oxides as Bifunctional Catalyst for Overall Water Splitting". Thesis, 2018. http://ndltd.ncl.edu.tw/handle/829f93.
Texto completo國立交通大學
材料科學與工程學系所
107
Global warming is the important issue nowadays. There are many technologies applied to overcome the problem. The research of renewable energy sources has now gained many attentions. The development of efficient catalysts from earth‐abundant elements are key to water splitting. Both of photoelectrochemical (PEC) water splitting and the oxygen evolution reactions (OER) are the promising methods. Herein, we demonstrated the transition metal oxide as the bifuntional catalyst. The copper oxide was first fabricated on the copper foil by a facile chemical synthesis route. Subsequently, the hydrogenated Cu2O (HCu2O) are prepared by thermal treatment in H2 atmosphere. The HCu2O exhibited remarkable performance for both H2 and O2 evolution in water splitting. The HCu2O showed great photocatalytic efficiency with photocurrent of 3.3mAcm-2 . In addition, the detail characterization techniques were used to study the potential of copper-based oxide for water splitting. Aside from photocatalytic HER applications, the HCu2O exhibited the electrocatalytic activity in OER with current density of 10 mAcm-2 at overpotential of 390 mV and the Tafel slope of 140 mVdec-1 . The OER as a half reaction of water splitting is a multistep electron-proton transfer coupled reaction. Therefore, the advanced operando/in-situ X-ray characterization techniques were used in this work. With the aid of these methods, the mechanism of charge transfers and the intermediates-derived active site were thoroughly investigated. Accordingly, the HCu2O is a promising candidate for overall water splitting owing to its excellent PEC/OER performance and low fabrication cost.
Yeh, Yu-Lin y 葉育霖. "Synthesis of rhodium and RGO coupled with K4Nb6O17 photocatalysts for overall photocatalytic water splitting". Thesis, 2014. http://ndltd.ncl.edu.tw/handle/fpyugd.
Texto completo國立東華大學
材料科學與工程學系
102
In this study, we combine H2 evolution photocatalyst with O2 evolution photocatalyst as well as utilize an aqueous NaI solution as I-/IO3- shuttle redox mediator in Z-scheme photocatalysis water splitting system.In the first part, We used exfoliation method to prepare the nanosheets photocatalyst, NS-K4Nb6O17, and loading Rh as cocatalyst, which was called H2 evolution photocatalyst. O2 evolution photocatalyst used WO3 loading 0.5wt%Pt as cocatalyst.We incorporated H2 evolution photocatalyst and O2 evolution photocatalyst into Z-scheme photocatalysis system. Also, we separately controlled the pH value of the reactant solution and the concentration of NaI. The combination of 1.5wt% Rh/NS-K4Nb6O17 with Pt/WO3 achieved a high H2 evolution rate (3849 μmol g-1 h-1) and O2 evolution rate(1898 μmol g-1 h-1) in the condition of pH=12 in 6mM NaI solution. In the second part, we added the approach of graphite oxide(GO) and Rh to explore the influence on Z-scheme photocatalysis system. We used solid state reaction to prepare H2 evolution photocatalyst, SS-K4Nb6O17. O2 evolution photocatalyst used WO3 loading 0.5wt%Pt as cocatalyst. We tried to add Rh and GO to Z-scheme photocatalysis system at pH=11 in 4mM NaI solution. First, we loaded Rh; second, we added GO, which found that it had a good photoactivity. In order to improve the contact of the surface between GO and photocatalyst, we loaded GO on photocatalyst(0.5wt%Rh/SS-K4Nb6O17) before the experiment and calcined them up to the efficacy(H2: 467μmoleg-1h-1、O2: 234μmoleg-1h-1).In the third part, we added GO to 1.5wt%Rh/NS-K4Nb6O17 photocatalyst.We found the best effect on the immersion of GO into reactant solution under UV light(H2: 4363μmoleg-1h-1、O2: 2082μmoleg-1h-1). Keyword: K4Nb6O17, Z-scheme, water splitting, Graphite oxide.
Su, Jian-Hau y 蘇健豪. "Z-scheme overall water splitting over KNb3O8 photocatalyst and visble-light photocatalytic inactivation of E.coli". Thesis, 2013. http://ndltd.ncl.edu.tw/handle/21707401187937046866.
Texto completo國立東華大學
材料科學與工程學系
101
The splitting of water into hydrogen and oxygen has been studied extensively, because of energy shortages in recent years. In the first part, this paper use the sol-gel and solid state sintering method to prepare potassium niobate (KNb3O8). We found the sol-gel method can use lower temperature to prepare potassium niobate(KNb3O8),and we can get higher hydrogen production activity. In the second part, we found potassium niobate (KNb3O8) has the highest bactericidal activity with 1wt% Ag by the photodeposition method. And the potassium niobate (KNb3O8) adds different amounts of Ag that can get different bactericidal activity. Final section, Z-scheme system consist to hydrogen production catalyst(KNb3O8)and oxygen production catalyst(BiVO4,WO3). I-/IO3- is redox mediator for Z-scheme system reaction. We found, different concentrations of NaI and PH value can affect the gas production activity.When 2mM concentration of NaI and PH value of 9 would have the best gas production activity in this paper. We found, the sol-gel method (KNb3O8) and commercial production of oxygen catalyst WO3 would have the best gas production activity in PH value of 9 (H2:538.72μmoleg-1h-1,O2:140.27μmoleg-1h-1) . Similarly we found the solid state sintering method (KNb3O8) and commercial production of oxygen catalyst WO3 would have the best gas production activity in PH value of 9. (H2:292.17μmoleg-1h-1,O2:130.83μmoleg-1h-1). Finally, we get the same result. The sol-gel method (KNb3O8) and BiVO4 would have the best gas production activity in PH value of 9. (H2:139.88μmoleg-1h-1,O2:49.5μmoleg-1h-1)
Qureshi, Muhammad. "Toward selective H2 evolution from overall water splitting and the trifluoromethylation of heteroarenes via heterogeneous photocatalysis". Diss., 2019. http://hdl.handle.net/10754/656661.
Texto completoMarino, Tiziana y Hermenegildo Garcia. "Gold based photocatalysis used in the overall water splitting in a membrane reactor and in organic synthesis". Thesis, 2011. http://hdl.handle.net/10955/1077.
Texto completoLa fotocatalisi eterogenea basata sull’utilizzo di catalizzatori di oro supportati si sta rivelando una tecnica promettente sia per la conversione di energia solare in energia chimica che per reazioni di sintesi organica, grazie alla possibilità di sfruttare la luce visibile come fonte di irradiazione e di ottenere processi ambientalmente sostenibili. Nel corso di questo lavoro di Dottorato è stata studiata l’attività fotocatalitica di diversi catalizzatori oro supportati, preparati secondo la procedura di deposizione-precipitazione, per la reazione di water splitting e per l'ossidazione parziale del benzene a fenolo. Nella prima parte del lavoro sperimentale, è stata investigata l’efficienza fotocatalitica di diversi campioni di Au/TiO2 e Au/CeO2 nelle reazioni di generazione di idrogeno e di ossigeno dall’acqua, rispettivamente. Gli effetti di parametri quali la quantità di oro, le dimensioni delle sue particelle, la concentrazione del catalizzatore ed il tipo di irradiazione luminosa, sono stati investigati al fine da evindenziare quali siano i principali fattori che influenzano il processo di water splitting. I risultati ottenuti lasciano supporre che l’oro svolga un duplice ruolo, ovvero che agisca come centro di raccolta di irradiazioni luminose oltre che come sito per la formazione di idrogeno ed ossigeno. Dai dati ottenuti sembrerebbe che la combinazione di quantità molto basse di oro (0.25% in peso) e dimensioni dell’ordine di 2-3 nm delle sue nanoparticelle favoriscano l’attività fotocatalitica dei sistemi Au/TiO2. Utilizzando radiazioni luminose con lunghezza d’onda vicine alla banda di assorbimento plasmonica dell’oro, le nanoparticelle assorbirebbero fotoni consentendo il trasferimento di elettroni nella banda di conduzione del supporto, con la contemporanea formazione di deficienze ellettroniche nelle particelle dell’oro. E’ stato studiato inoltre un metodo innovativo per la sintesi di CeO2, utilizzato come supporto per la generazione di ossigeno dall’acqua e che ha consentito l’ottenimento di particelle di catalizzatore di circa 5 nm. I risultati sperimentali hanno messo in evidenza come le proprietà fotocatalitiche del semiconduttore siano strettamente correlate alle dimensioni delle sue particelle. La presenza dell’oro sembra influenzare positivamente la sua attività fotocatalitica sotto irradiazione con luce visibile. Successivamente, i catalizzatori Au/TiO2 e Au/CeO2, sono stati sperimentati nel processo di water splitting utilizzando un sistema a membrana, al fine di ottenere la generazione simultanea di idrogeno ed ossigeno. Il processo, che ha previsto l’utilizzo di una membrana di nafion modificata e di solfato ferrico, ha portato allo sviluppo dei due gas in quantità stechiometriche sotto irradiazione con luce visibileIl processo di water splitting per la generazione di idrogeno è stato inoltre studiato sperimentando Au/TiO2 supportato su carboni attivi preparati attraverso differenti metodi di attivazione, al fine di analizzare l’influenza della funzionalizzazione sul processo fotocatalitico di generazione di idrogeno dall’acqua. Carboni attivi con pH basico sembrano svolgere un’influenza positiva sull’efficienza fotocatalitica di Au/TiO2 sotto irradiazione con luce visibile. Infine, nell’ultima parte del lavoro di tesi, catalizzatori Au/TiO2 sono stati testati nella reazione di ossidazione parziale del benzene a fenolo in un reattore batch. L’utilizzo di campioni oro supportati ha consentito il miglioramento delle rese di fenolo rispetto a quelle registrate per il TiO2 non modificato, sebbene la formazione di prodotti secondari, quali il benzochinone, rappresenti il principale incoveniente del processo.
University of Calabria,DOCTORAL SCHOOL “PITAGORA"