Hydrogen production via a sulfur-sulfur thermochemical water-splitting cycle

AuYeung, Nicholas J.

14 October 2011

Thermochemical water splitting cycles have been conceptualized and researched for over half a century, yet to this day none are commercially viable. The heavily studied Sulfur-Iodine cycle has been stalled in the early development stage due to a difficult HI-H₂O separation step and material compatibility issues. In an effort to avoid the azeotropic HI-H₂O mixture, an imidazolium-based ionic liquid was used as a reaction medium instead of water. Ionic liquids were selected based on their high solubility for SO₂, I₂, and tunable miscibility with water. The initial low temperature step of the Sulfur-Iodine cycle was successfully carried out in ionic liquid reaction medium. Kinetics of the reaction were investigated by I₂ colorimetry. The reaction also evolved H₂S gas, which led to the conceptual idea of a new Sulfur-Sulfur thermochemical cycle, shown below: / 4I₂(l)+4SO₂(l)+8H₂O(l)↔4H₂SO₄(l)+ 8HI(l) / 8HI(l)+H₂SO₄(l)↔ H₂S(g)+4H₂O(l)+4I₂(l) / 3H₂SO₄(g)↔ 3H₂O(g)+3SO₂(g)+1½O₂(g) / H₂S(g)+2H₂O(g)↔ SO₂(g)+3H₂(g) / The critical step in the Sulfur-Sulfur cycle is the steam reformation of H₂S. This highly endothermic step is shown to successfully occur at temperatures in excess of 800˚C in the presence of a molybdenum catalyst. A parametric study varying the H₂O:H₂S ratio, temperature, and residence time in a simple tubular quartz reactor was carried out and Arrhenius parameters were estimated. All reactive steps of the Sulfur-Sulfur cycle have been either demonstrated previously or demonstrated in this work. A theoretical heat-to-hydrogen thermal efficiency is estimated to be 55% at a hot temperature of 1100 K and 59% at 2000 K. As a highly efficient, all-fluid based thermochemical cycle, the Sulfur-Sulfur cycle has great potential for feasible process implementation for the transformation of high quality heat to chemical energy. / Graduation date: 2012

thermochemical water-splitting cycle

thermochemical hydrogen production

hydrogen

sulfur-sulfur cycle

sulfur-iodine cycle

ionic liquids

Thermochemistry

Hydrogen as fuel

First-principles calculations of polaronic correlations and reactivity of oxides: manganites, water oxidation and Pd/rutile interface

Sotoudeh, Mohsen

12 December 2018

No description available.

530

Physik (PPN621336750)

First-principles density functional theory study of novel materials for solar energy conversion and environment applications

Ullah, Habib

January 2018

To design an efficient solar energy conversion device, theoretical input is extremely important to provide the basic guideline for experimental scientists, to fabricate the most efficient, cheap, and stable device with less efforts. This desire can be made possible if computational scientist use a proper theoretical protocol, design an energy material, then the experimentalist will only invest weeks or months on the synthetic effort. This thesis highlights my recent efforts in this direction. Monoclinic BiVO4 is has been using as a photocatalyst due to its stability, cheap, easily synthesizable, narrow band gap and ideal VB (-6.80 eV vs vacuum) but inappropriate CB (-4.56 eV vs vacuum) edge position, responsible for its low efficiency. We have carried out a comprehensive experimental and periodic density functional theory (DFT) simulations of the pristine, Oxygen defective (Ov), Se doped monoclinic BiVO4 and heterojunction with Selenium (Se-BiVO4), to improve not only its CB edge position but photocatalytic and charge carrier properties. It is found that Ov (1% Oxygen vacancy) and mild doped BiVO4 (1 to 2% Se) are thermodynamically stable, have ideal band edges ~ -4.30 eV), band gaps (~1.96 eV), and small effective masses of electrons and holes. We have also investigated the contribution of Se to higher performance by effecting morphology, light absorption and charge transfer properties in heterojunction. Finally, it is found that Se makes a direct Z-scheme (band alignments) with BiVO4 where the photoexcited electron of BiVO4 recombine with the VB of Se, consequences electron-hole separation at Se and BiVO4, respectively, as a result, enhanced photocurrent is obtained. Theoretical study of β-TaON in the form of primitive unit cell, supercell and its N, Ta, and O terminated surfaces are carried out with the help of periodic DFT. Optical and electronic properties of all these different species are simulated, which predict TaON as the best candidate for photocatalytic water splitting contrast to their Ta2O5 and Ta3N5 counterparts. The calculated bandgap, valence band, and conduction band edge positions predict that β-TaON should be an efficient photoanodic material. The valence band is made up of N 2p orbitals with a minor contribution from O 2p, while the conduction band is made up of Ta 5d. Turning to thin films, the valence band maximum; VBM (−6.4 eV vs. vacuum) and the conduction band minimum; CBM (−3.3 eV vs. vacuum) of (010)-O terminated surface are respectively well below and above the redox potentials of water as required for photocatalysis. Charge carriers have smaller effective masses than in the (001)-N terminated film (VBM −5.8 and CBM −3.7 eV vs. vacuum). However, due to wide band gap (3.0 eV) of (010)-O terminated surface, it cannot absorb visible wavelengths. On the other hand, the (001)-N terminated TaON thin film has a smaller band gap in the visible region (2.1 eV) but the bands are not aligned to the redox potential of water. Possibly a mixed phase material would produce an efficient photoanode for solar water splitting, where one phase performs the oxidation and the other reduction. Computational study of an optically transparent, near-infrared-absorbing low energy gap conjugated polymer, donor−acceptor−donor (D-A-D) with promising attributes for photovoltaic application is reported herein. The D and A moiety on the polymeric backbone have been found to be responsible for tuning the band gap, optical gap, open circuit (Voc) and short-circuit current density (Jsc) in the polymers solar cells (PSC). Reduction in the band gap, high charge transformation, and enhanced visible light absorption in the D-A-D system is because of strong overlapping of molecular orbitals of D and A. In addition, the enhanced planarity and weak steric hindrance between adjacent units of D-A-D, resulted in red-shifting of its onset of absorption. Finally, PSC properties of the designed D-A-D was modeled in the bulk heterojunction solar cell, which gives theoretical Voc of about 1.02 eV. DFT study has been carried out to design a new All-Solid-State dye-sensitized solar cell (SDSC), by applying a donor-acceptor conjugated polymer instead of liquid electrolyte. The typical redox mediator (I1−/I3−) is replaced with a narrow band gap, hole transporting material (HTM). A unique “upstairs” like band energy diagram is created by packing N3 between HTM and TiO2. Our theoretical simulations prove that the proposed configuration will be highly efficient as the HOMO level of HTM is 1.19 eV above the HOMO of sanitizer (dye); providing an efficient pathway for charge transfer. High short-circuit current density and power conversion efficiency is promised from the strong overlapping of molecular orbitals of HTM and sensitizer. A low reorganization energy of 0.21 eV and exciton binding energy of 0.55 eV, confirm the high efficiency of HTM. Theoretical and experimental studies of a series of four porphyrin-furan dyads were designed and synthesized, having anchoring groups, either at meso-phenyl or pyrrole-β position of a zinc porphyrin based on donor–π–acceptor (D–π–A) approach. The porphyrin macrocycle acts as donor, furan hetero cycle acts as π-spacer and either cyanoacetic acid or malonic acid group acts as acceptor. Optical bandgap, natural bonding, and molecular bonding orbital (HOMO–LUMO) analysis confirm the high efficiency pyrrole-β substituted zinc porphyrins contrast to meso-phenyl dyads. DFT study of polypyrrole-TiO2 composites has been carried out to explore their optical, electronic and charge transfer properties for the development of an efficient photocatalyst. Titanium dioxide (Ti16O32) was interacted with a range of pyrrole (Py) oligomers to predict the optimum composition of nPy-TiO2 composite with suitable band structure for efficient photocatalytic properties. The study has revealed that Py-Ti16O32 composites have narrow band gap and better visible light absorption capability compared to individual constituents. A red-shifting in λmax, narrowing band gap, and strong intermolecular interaction energy (-41 to −72 kcal/mol) of nPy-Ti16O32 composites confirm the existence of strong covalent type interactions. Electron−hole transferring phenomena are simulated with natural bonding orbital analysis where Py oligomers found as donor and Ti16O32 as an acceptor in nPy-Ti16O32 composites. Sensitivity and selectivity of polypyrrole (PPy) towards NH3, CO2 and CO have been studied at DFT. PPy oligomers are used both, in the doped (PPy+) and neutral (PPy) form, for their sensing abilities to realize the best state for gas sensing. Interaction energies and amount of charges (NBO and Mulliken charge analysis) are simulated which reveal the sensing ability of PPy towards these gases. PPy, both in doped and neutral state, is more sensitive to NH3 compared to CO2 and CO. More interestingly, NH3 causes doping of PPy and de-doping of PPy+, providing evidence that PPy/PPy+ is an excellent sensor for NH3 gas. UV-vis and UV-vis-near-IR spectra of nPy, nPy+, and nPy/nPy+-X complexes demonstrate strong interaction of PPy/PPy+ with these atmospheric gases. The applications of graphene (GR) and its derivatives in the field of composite materials for solar energy conversion, energy storage, environment purification and biosensor applications have been reviewed. The vast coverage of advancements in environmental applications of GR-based materials for photocatalytic degradation of organic pollutants, gas sensing and removal of heavy metal ions is presented. Additionally, the presences of graphene composites in the bio-sensing field have been also discussed in this review.

333.79

Etude par DFT de photocatalyseurs pour des applications en photodissociation de l'eau / DFT study of photocatalysts for water-splitting applications

Curutchet, Antton

24 June 2019

Dans une société qui peine à renoncer à l'utilisation des énergies fossiles, la production d'hydrogène à partir d'eau par photocatalyse solaire est une alternative que les chimistes se doivent d'explorer. La mise en place de cette solution est conditionnée à la résolution de deux problèmes majeurs : augmenter l'efficacité de la conversion solaire par le développement de nouveaux semi-conducteurs, et améliorer la réactivité en surface par le développement de co-catalyseurs efficaces. Dans un premier temps, nous avons contribué à l'étude d'une nouvelle famille de semi-conducteurs par des calculs ab initio DFT. Différentes propriétés clés ont été calculées et comparées aux valeurs expérimentales. Nous avons montré que pour une même famille de matériaux, l'absorption peut être contrôlée par modification de la composition.Ensuite, nous nous sommes focalisés sur la réaction d'oxydation de l'eau (OER). Pour cette réaction les catalyseurs de type oxyhydroxydes et leurs dérivés sont très prometteurs car à la fois efficaces et contenant des éléments abondants sur Terre, mais la compréhension de son mécanisme reste limitée. Sur le composé modèle CoOOH, nous en avons réalisé une analyse approfondie par une étude exhaustive des intermédiaires ainsi que par modélisation explicite du potentiel électrochimique. Nos études ont montré la nécessite de prendre en compte plusieurs sites réactionnels dans la détermination des mécanismes d'oxydation de l'eau sur la surface de ces catalyseurs. Enfin, une étude préliminaire de l'utilisation de la biomasse a été menée, dans le but de combiner valorisation de la biomasse et production d'hydrogène. Le cas de l'oxydation du glycérol est envisagé. / In a society struggling to waive the use of fossil fuels, hydrogen production from water by solar photocatalysis is a alternative chemists have to consider. Setting up of this solutions asks to tackle two major issues : increase solar energy conversion by developing new semiconductors, and enhance the surface reactivity by developing efficient cocatalysts.First, DFT \emph{ab initio} calculations were carried out on a new family of semiconductor materials. Different key properties were computed and compared to experimental values. We showed that for a same material family, absorption can be controlled by changing the composition.Then, we focused on Oxygen Evolution Reaction (OER). For this reaction oxyhydroxides catalysts and their derivatives seem promising as both efficient and containing earth-abundant elements, but the understanding of its mechanism still remains unclear. On CoOOH model compound, we realised an extended analysis by a comprehensive study of intermediates and by explicit modelling of electrochemical potential. Our studies showed that taking into account several reactive sites is necessary to determine the OER mechanism on these catalysts' surface.Last, a preliminary study of biomass use was carried, in order to combine its valorization along with hydrogen production. The case of glycerol photoreforming is considered.

Chimie théorique

DFT

Modélisation

Photocatalyse

Hydrogène

Photodissociation

Photo-électrocatalyse

Semiconducteurs

Computationnal chemistry

DFT

Photocatalysis

Hydrogen

Water-splitting

Photoelectrocatalysis

Semiconductors

Biomass

Photocatalytic And Photoelectrochemical Water Splitting Over Ordered Titania Nanotube Arrays

Karslioglu, Osman

01 February 2009

The objective of this study was to investigate photocatalytic water splitting over ordered TiO2 nanotube arrays. Synthesis of ordered nanotube arrays of titania, as a micron thick film on a titanium foil was accomplished by electrochemical anodization methods defined in the literature. Effect of two types of electrolyte (aqueous and organic) on the micro-morphology was observed by scanning electron microscopy. Optimum anodization times for the TiO2 nanotube electrodes, synthesized in ethylene glycol electrolyte, were different for acidic and basic electrolytes. Optimum times were determined as 2 hours in acidic and 4 hours in basic solutions. An H-type cell was constructed using a two side anodized titanium foil aiming the photocatalytic, stoichiometric and separate evolution of H2/O2 from the splitting of water. Gas evolution was observed at a rate of approximately 1 mL/h in the anode and 0.5 mL/h in the cathode, which implied the reverse of the desired stoichiometry. As the surface was corroded in that experimental conditions, electrochemical properties of the synthesized films were investigated by cyclic voltammetry (CV) at milder conditions. CV showed the reduction of Ti4+ to Ti3+, beginning at -0.2 V (vs. Ag/AgCl). Since the process is accompanied by proton intercalation to the oxide, non-annealed samples showed higher currents in that region. Non-annealed samples showed no photocurrent. Photocurrents obtained in this work, on the average 0.1-0.2 mA/cm2, were one order of magnitude lower than the similar studies in the literature.

TP Chemical Engineering 155-156

Highly Efficient CIGS Based Devices for Solar Hydrogen Production and Size Dependent Properties of ZnO Quantum Dots

Jacobsson, T. Jesper

January 2014

Materials and device concepts for renewable solar hydrogen production, and size dependent properties of ZnO quantum dots are the two main themes of this thesis. ZnO particles with diameters less than 10 nm, which are small enough for electronic quantum confinement, were synthesized by hydrolysis in alkaline zinc acetate solutions. Properties investigated include: the band gap - particle size relation, phonon quantum confinement, visible and UV-fluorescence as well as photocatalytic performance. In order to determine the absolute energetic position of the band edges and the position of trap levels involved in the visible fluorescence, methods based on combining linear sweep voltammetry and optical measurements were developed. The large band gap of ZnO prevents absorption of visible light, and in order to construct devices capable of utilizing a larger part of the solar spectrum, other materials were also investigated, like hematite , Fe2O3, and CIGS, CuIn1-xGaxSe2. The optical properties of hematite were investigated as a function of film thickness on films deposited by ALD. For films thinner than 20 nm, a blue shift was observed for both the absorption maximum, the indirect band gap as well as for the direct transitions. The probability for the indirect transition decreased substantially for thinner films due to a suppressed photon/phonon coupling. These effects decrease the visible absorption for films thin enough for effective charge transport in photocatalytic applications. CIGS was demonstrated to be a highly interesting material for solar hydrogen production. CIGS based photocathodes demonstrated high photocurrents for the hydrogen evolution half reaction. The electrode stability was problematic, but was solved by introducing a modular approach based on spatial separation of the basic functionalities in the device. To construct devices capable of driving the full reaction, the possibility to use cells interconnected in series as an alternative to tandem devices were investigated. A stable, monolithic device based on three CIGS cells interconnected in series, reaching beyond 10 % STH-efficiency, was finally demonstrated. With experimental support from the CIGS-devices, the entire process of solar hydrogen production was reviewed with respect to the underlying physical processes, with special focus on the similarities and differences between various device concepts.

ZnO

Nanoparticles

Quanum Dots

Size Dependent Properties

Hematite

CIGS

Solar Water Splitting

Hydrogen Production

PEC

Photoelectrochemical cells

PV-electrolysis

Cubic Silicon Carbide For Direct Photoelectrochemical Water Splitting / Carbure de silicium pour la dissociation photoélectrochimique directe de l'eau

Tengeler, Sven

09 November 2017

Le but de ce travail était l’analyse de la capacité de carbure de silicium cubique à servir de matériau d’anode pour le fractionnement de l’eau photo-électrochimique direct. Les données récoltées (principalement la spectroscopie photo-électronique, électrochimie, Raman et spectroscopie UV-Vis) permettaient de ramener la faible efficacité de carbure de silicium cubique dopé n pour le dégagement d’oxygéne à des problèmes fondamentaux.Principalement le courant photoélectrique réalisable est limité par le flux des trous générés par photo à la surface de semi-conducteur. Comme carbure de silicium cubique est un semi-conducteur indirect, le faible coefficient d’absorption en combinaison avec une dotation élevée et une petite longueur de diffusion de trou ont été déterminés comme les facteurs limitant. Un film épitaxial additionnel de carbure de silicium n-cubique a entraîné une augmentation signifiante du courant photoélectrique maximal.La tension photoélectrique réalisable et les pertes dues aux recombinaisons dépendent principalement des propriétés de surface. L’utilisation des minces couches de catalyseur s’est révélé prometteur pour améliorer les deux propriétés même si cette technique a besoin d'optimisation parce que des états défectueux à l’interface limitent la tension photoélectrique. / The goal of this work was to investigate cubic silicon carbide as anode material for direct photoelectrochemical water splitting. From the performed measurements (mostly photoelectron spectroscopy, electrochemical measurements, Raman and UV-Vis spectroscopy) n-type cubic silicon carbide’s low oxygen evolution efficiency could be related to some fundamental problems.Primarily, the attainable photocurrent is limited by the flux of photo generated holes to the semiconductor surface. As cubic silicon carbide is a indirect semiconductor, the low absorption coefficient in combination with a high doping concentration and low hole diffusion length were determined as limiting factors. An additional epitaxial n- cubic silicon carbide film resulted in a significant improvement of the photocurrent.The obtainable photovoltage and recombination losses are mostly dependent on the surface properties. While a buried junction between the silicon carbide and a thin catalyst layer has proven to be promising for improving both properties, it still needs optimization, as Fermi level pinning from interface defect states drastically reduces the photovoltage.

Production d'hydrogéne

Carbure de silicium

Photoélectrolyse

Décomposition de l'eau

Stockage d'énergie

Hydrogen production

Silicon carbide

Photoelectrolysis

Water splitting

Energy storage

540

Desenvolvimento de um dispositivo fotoeletroqu?mico a base de g-C3N4, Cu2O e CuO para clivagem da ?gua em H2 e O2

Almeida, Monique Rocha

22 August 2016

Submitted by Jos? Henrique Henrique (jose.neves@ufvjm.edu.br) on 2017-03-24T21:23:22Z No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) monique_rocha_almeida.pdf: 4635045 bytes, checksum: 2d203824a390ae82a5006e68b621c98b (MD5) / Approved for entry into archive by Rodrigo Martins Cruz (rodrigo.cruz@ufvjm.edu.br) on 2017-04-20T19:40:16Z (GMT) No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) monique_rocha_almeida.pdf: 4635045 bytes, checksum: 2d203824a390ae82a5006e68b621c98b (MD5) / Made available in DSpace on 2017-04-20T19:40:16Z (GMT). No. of bitstreams: 2 license_rdf: 0 bytes, checksum: d41d8cd98f00b204e9800998ecf8427e (MD5) monique_rocha_almeida.pdf: 4635045 bytes, checksum: 2d203824a390ae82a5006e68b621c98b (MD5) Previous issue date: 2016 / Universidade Federal dos Vales do Jequitinhonha e Mucuri (UFVJM) / A convers?o de energia solar em energia qu?mica usando c?lulas fotoeletroqu?micas ? uma estrat?gia interessante para armazenar energia. C?lulas fotoeletroqu?micas s?o dispositivos constitu?dos de fotoeletrodos semicondutores que absorvem luz com energia maior ou igual a energia de bandgap do semicondutor e geram cargas reativas (el?trons e buracos) na superf?cie dos fotoeletrodos capazes de promover a redu??o e oxida??o da ?gua em H2 e O2, respectivamente. Nesta disserta??o, quatro fotoeletrodos de g-C3N4, g-C3N4/Cu1%, g- C3N4/Cu5% e Cu2O/CuO foram preparados com o objetivo de desenvolver uma c?lula fotoeletroqu?mica para clivagem da ?gua em H2 e O2 de forma espont?nea. As medidas de difratometria de raios X confirmaram a presen?a das fases g-C3N4 e Cu2O/CuO nos fotoeletrodos. As imagens de MEV mostraram que os materiais ? base de g-C3N4 possuem morfologia do tipo esponja, enquanto a heterojun??o Cu2O/CuO ? formada por nanopart?culas de forma indefinida. Medidas de reflect?ncia difusa mostraram que o acoplamento do g-C3N4 e Cu2O/CuO resulta em uma melhora significativa na absor??o ?ptica dos fotoeletrodos. Medidas de ?rea espec?fica indicaram que os nanomateriais ? base de g-C3N4 tem alta ?rea superficial (?100 m2 g?1), enquanto a ?rea espec?fica da heterojun??o Cu2O/CuO foi de 17 m2 g?1. Os resultados de redu??o ? temperatura programada evidenciaram a forma??o das heterojun??es. Os testes fotoeletroqu?micos de produ??o de O2 a partir da ?gua usando luz vis?vel indicaram que em potenciais an?dicos, apenas o fotoanodo de g-C3N4 foi est?vel apresentando uma densidade de fotocorrente de 16 ?A cm?2 que corresponde a uma efici?ncia de convers?o de luz de 0,014%. Em potenciais cat?dicos, a maior densidade de fotocorrente (60 ?A cm?2) foi obtida para o fotoeletrodo Cu2O/CuO. A efici?ncia de convers?o de luz do fotocatodo de Cu2O/CuO foi de 0,029%. Com base nos dados obtidos, uma c?lula fotoeletroqu?mica p-n foi constru?da usando a heterojun??o Cu2O/CuO como fotocatodo e g- C3N4 como fotoanodo. Esta c?lula gerou uma densidade de fotocorrente in operando de 0,62 ?A cm?2 e uma fotovoltagem de 0,62 V. A efici?ncia de convers?o solar da fotoc?lula foi de 0,004% sob irradia??o de luz vis?vel. Apesar da baixa efici?ncia obtida, espera-se que esta disserta??o possa servir de inspira??o para o desenvolvimento de novos dispositivos fotoeletroqu?micos para clivagem da ?gua em H2 e O2, usando luz vis?vel. / Disserta??o (Mestrado) ? Programa de P?s-Gradua??o em Qu?mica, Universidade Federal dos Vales do Jequitinhonha e Mucuri, 2016. / The conversion of solar energy into chemical energy using photoelectrochemical cells is an interesting strategy to store energy. Photoelectrochemical cells are made up of semiconductor photoelectrodes that absorb light with energy equal or higher than the bandgap energy of the semiconductor to generate reactive charges (electrons and holes) on the surface of the photoelectrodes, which can promote the oxidation and reduction reactions of water to form H2 and O2, respectively. In this dissertation, four photoelectrodes of g-C3N4, g-C3N4/Cu1%, g- C3N4/Cu5%, and Cu2O/CuO were prepared in order to develop a photoelectrochemical cell for spontaneous water splitting into H2 and O2. The X-ray diffraction patterns confirmed the presence of g-C3N4 and Cu2O/CuO phases in the photoelectrodes. The SEM images showed that the materials based on g-C3N4 have sponge-like morphology, whereas the Cu2O/CuO heterojunction is formed by nanoparticles with undefined shapes. Diffuse reflectance measurements showed that coupling g-C3N4 and Cu2O/CuO results in a significant improvement in optical absorption of the photoelectrodes. Surface area measurements indicated that the nanomaterials based on g-C3N4 have high surface areas (?100 m2 g?1), while the specific area for the Cu2O/CuO heterojunction was 17 m2 g?1. The temperature programmed reduction results evidenced the formation of the heterojunctions. The photoelectrochemical assays of O2 production from water using visible light indicated that at anodic potentials, only the photoanode g-C3N4 was stable showing a photocurrent density of 16 ?A cm?2, which corresponds to a light conversion efficiency of 0.014%. At cathodic potentials, the higher photocurrent density (60 ?A cm?2) was obtained for the Cu2O/CuO photoelectrode. The light conversion efficiency of the Cu2O/CuO photocathode was 0.029%. Based on the obtained data, a p-n photoelectrochemical cell was constructed using the Cu2O/CuO heterojunction as the photocathode and g-C3N4 as the photoanode. This photocell generated a photocurrent density in operando of 0.62 ?A cm?2 and photovoltage of 0.62 V. The light conversion efficiency of the photocell was 0.004% under visible light irradiation. Despite the low efficiency obtained for the p-n photocell, it is expected that this dissertation may serve of inspiration for the development of new photoelectrochemical devices for water splitting into H2 and O2 using visible light.

C?lulas fotoeletroqu?micas

Clivagem da ?gua

Hidrog?nio

Fotoanodo

Fotocatodo

Photoelectrochemical cells

Water splitting

Hydrogen

Photoanode

Photocathode

Efeito da adição de polivinilbutiral na obtenção de filmes de TiO2 por dip-coating, sua caracterização microestrutural e fotoeletrolítica na produção de hidrogênio a partir da água

Teloeken, Ana Caroline

January 2015

Este trabalho investigou a obtenção de filmes de TiO2 por sol-gel e dipcoating (SGDC) e sua caracterização microestrutural e como fotocatalisador para a produção de hidrogênio a partir da água. Os precursores e reagentes utilizados foram: propóxido de titânio, ácido acético, etanol anidro, acetilacetona, Triton X-100 e polivinilbutiral (PVB). Foram preparadas 2 soluções precursoras, uma com PVB e outra sem. Foram produzidos filmes com 1, 2 e 3 camadas através da técnica de dip-coating. Os filmes foram tratados termicamente a 400, 500 e 600ºC, com uma taxa de 100ºC/h e um patamar de 2 h. O TiO2 sintetizado e os filmes produzidos foram caracterizados por difração de raios X (DRX) quanto à cristalinidade, fases presentes e tamanho de cristalito; microscopia eletrônica de varredura (MEV), adsorção de nitrogênio (método BET), análises termogravimétricas (ATG) e termodiferenciais (ATD), elipsometria espectroscópica, perfilometria óptica, espectroscopia Raman e de reflectância difusa (determinação do band gap). Após o tratamento térmico os filmes apresentaram uma microestrutura bastante irregular e com muitas trincas, com a presença da fase anatase em todas as temperaturas de tratamento térmico, e um teor de 3,7% de rutilo à 600ºC. O band gap dos filmes aumentou com a quantidade de camadas adicionadas, com a elevação da temperatura de tratamento térmico e adição de PVB. As medidas de fotocorrente foram realizadas no escuro e sob iluminação de lâmpada de Xe com 250W (simulador de luz solar de 1,5AM). A maior fotocorrente medida foi de 12 μA a 0,5V. A produção de H2 aumentou linearmente com o tempo de exposição para ambas as amostras com PVB. Foi possível relacionar a adição do PVB com o favorecimento da fotoatividade dos filmes de TiO2. / This work has investigated the effect of polyvinyl butyral addition in the synthesis of TiO2 films by sol-gel and dip-coating, their microstructural features and their photoelectrochemical activity for water-splitting hydrogen production. The precursors and reagents used were: titanium propoxide, acetic acid, anhydrous ethanol, acetylacetone, Triton X-100 and polyvinyl butyral (PVB). Two precursor solutions were prepared: one with PVB and another without it. The dip-coating technique was used to produce films with 1, 2 and 3 layers. The films were heat treated at 400, 500 and 600ºC, at a rate of 100°C/h and dwelling time of 2h. Afterwards the synthesized films were characterized by X-ray diffraction (XRD); scanning electron microscopy (SEM), nitrogen adsorption (BET method), thermogravimetric (TGA) and differential thermal analysis (DTA), spectroscopic ellipsometry, optical profilometry, Raman and diffuse reflectance spectroscopy (determination of the band gap). The films after heat treatment showed a very irregular microstructure with many cracks. The anatase phase was presented in all temperatures and a small content of rutile at 600 °C (around 3.7%) was identified. The band gap of the films increased with the number of layers, heat treatment and addition of PVB. The photocurrent measurements were carried out in the dark and under illumination with 250W Xe, using a sunlight simulator (1,5AM). The highest photocurrent was 12A at 0.5V. The H2 production increased linearly with time of exposure for both samples with PVB. Therefore, it was possible to relate the addition of PVB with improvement the photoactivity of TiO2 films.

Dióxido de titânio

Sol-gel

Produção de hidrogênio

Fotoeletroquímica

Water splitting

Polyvinyl butyral

TiO2 films

Dip-coating

Hydrogen production

Efeito da adição de polivinilbutiral na obtenção de filmes de TiO2 por dip-coating, sua caracterização microestrutural e fotoeletrolítica na produção de hidrogênio a partir da água

Teloeken, Ana Caroline

January 2015

Este trabalho investigou a obtenção de filmes de TiO2 por sol-gel e dipcoating (SGDC) e sua caracterização microestrutural e como fotocatalisador para a produção de hidrogênio a partir da água. Os precursores e reagentes utilizados foram: propóxido de titânio, ácido acético, etanol anidro, acetilacetona, Triton X-100 e polivinilbutiral (PVB). Foram preparadas 2 soluções precursoras, uma com PVB e outra sem. Foram produzidos filmes com 1, 2 e 3 camadas através da técnica de dip-coating. Os filmes foram tratados termicamente a 400, 500 e 600ºC, com uma taxa de 100ºC/h e um patamar de 2 h. O TiO2 sintetizado e os filmes produzidos foram caracterizados por difração de raios X (DRX) quanto à cristalinidade, fases presentes e tamanho de cristalito; microscopia eletrônica de varredura (MEV), adsorção de nitrogênio (método BET), análises termogravimétricas (ATG) e termodiferenciais (ATD), elipsometria espectroscópica, perfilometria óptica, espectroscopia Raman e de reflectância difusa (determinação do band gap). Após o tratamento térmico os filmes apresentaram uma microestrutura bastante irregular e com muitas trincas, com a presença da fase anatase em todas as temperaturas de tratamento térmico, e um teor de 3,7% de rutilo à 600ºC. O band gap dos filmes aumentou com a quantidade de camadas adicionadas, com a elevação da temperatura de tratamento térmico e adição de PVB. As medidas de fotocorrente foram realizadas no escuro e sob iluminação de lâmpada de Xe com 250W (simulador de luz solar de 1,5AM). A maior fotocorrente medida foi de 12 μA a 0,5V. A produção de H2 aumentou linearmente com o tempo de exposição para ambas as amostras com PVB. Foi possível relacionar a adição do PVB com o favorecimento da fotoatividade dos filmes de TiO2. / This work has investigated the effect of polyvinyl butyral addition in the synthesis of TiO2 films by sol-gel and dip-coating, their microstructural features and their photoelectrochemical activity for water-splitting hydrogen production. The precursors and reagents used were: titanium propoxide, acetic acid, anhydrous ethanol, acetylacetone, Triton X-100 and polyvinyl butyral (PVB). Two precursor solutions were prepared: one with PVB and another without it. The dip-coating technique was used to produce films with 1, 2 and 3 layers. The films were heat treated at 400, 500 and 600ºC, at a rate of 100°C/h and dwelling time of 2h. Afterwards the synthesized films were characterized by X-ray diffraction (XRD); scanning electron microscopy (SEM), nitrogen adsorption (BET method), thermogravimetric (TGA) and differential thermal analysis (DTA), spectroscopic ellipsometry, optical profilometry, Raman and diffuse reflectance spectroscopy (determination of the band gap). The films after heat treatment showed a very irregular microstructure with many cracks. The anatase phase was presented in all temperatures and a small content of rutile at 600 °C (around 3.7%) was identified. The band gap of the films increased with the number of layers, heat treatment and addition of PVB. The photocurrent measurements were carried out in the dark and under illumination with 250W Xe, using a sunlight simulator (1,5AM). The highest photocurrent was 12A at 0.5V. The H2 production increased linearly with time of exposure for both samples with PVB. Therefore, it was possible to relate the addition of PVB with improvement the photoactivity of TiO2 films.

Dióxido de titânio

Sol-gel

Produção de hidrogênio

Fotoeletroquímica

Water splitting

Polyvinyl butyral

TiO2 films

Dip-coating

Hydrogen production