Nanoscaled Structures in Ruthenium Dioxide Coatings

Malmgren, Christine

January 2009

<p>An essential ingredient in the generation of environmentally compatible pulp bleaching chemicals is sodium chlorate. Chlorate is produced in electrochemical cells, where the electrodes are the key components. In Sweden the so-called DSA !R electrodes with catalytic coatings have been produced for more than 35 years. The production of chlorate uses a large amount of electric energy, and a decrease of just five percent of this consumption would, globally, decrease the consumption of electrical energy corresponding to half a nuclear power reactor. The aim of this project is to improve the electrode design on the nanoscale to decrease the energy consumption. The success of the DSA!R depends on the large catalytic area of the coating, however, little is known about the actual structure at the nanometer level. To increase the understanding of the nanostructure of these coatings, we used a number of methods, including atomic force microscopy, transmission electron microscopy, X-ray diffraction, porosimetry, and voltammetric charge. We found that the entire coating is built up of loosely packed rutile mono-crystalline 20 − 30 nm sized grains. The small grain sizes give a the large area, and consequently, lower cell-voltage and reduced energy consumption. A method to control the grain size would thus be a way to control the electrode efficiency. To alter the catalytically active area, we made changes in the coating process parameters. We found a dependency of the crystal-grain sizes on the choice of ruthenium precursor and processing temperature. The use of ruthenium nitrosyl nitrate resulted in smaller grains than ruthenium chloride and lowering the temperature tended to favour smaller grains. A more radical way would be to create a totally different type of electrode, manufactured in another way than using the 1965 DSA !R recipe. Such new types of electrodes based on, for example, nanowires or nanoimprint lithography, are discussed as future directions.</p>

Bleaching chemicals

sodium chlorate

ruthenium dioxide

electrodes

crystallites

nanowires

microscopy

diffraction

electrocatalytic area

reduced energy consumption

NATURAL SCIENCES

NATURVETENSKAP

EXAFS structural analysis on metal binding sites in wood pulp and a brief study on chelation of metals in bleaching

Ow Yang, Giselle Bei

04 1900

No description available.

Ligands

Chelation

Iron compounds

Scale (Deposits)

Metals

Wood-pulp

Bleaching

Absorption spectra

Crystallites

Chemical bonds

Bleaching effluents

Nanoscaled Structures in Ruthenium Dioxide Coatings

Malmgren, Christine

January 2009

An essential ingredient in the generation of environmentally compatible pulp bleaching chemicals is sodium chlorate. Chlorate is produced in electrochemical cells, where the electrodes are the key components. In Sweden the so-called DSA !R electrodes with catalytic coatings have been produced for more than 35 years. The production of chlorate uses a large amount of electric energy, and a decrease of just five percent of this consumption would, globally, decrease the consumption of electrical energy corresponding to half a nuclear power reactor. The aim of this project is to improve the electrode design on the nanoscale to decrease the energy consumption. The success of the DSA!R depends on the large catalytic area of the coating, however, little is known about the actual structure at the nanometer level. To increase the understanding of the nanostructure of these coatings, we used a number of methods, including atomic force microscopy, transmission electron microscopy, X-ray diffraction, porosimetry, and voltammetric charge. We found that the entire coating is built up of loosely packed rutile mono-crystalline 20 − 30 nm sized grains. The small grain sizes give a the large area, and consequently, lower cell-voltage and reduced energy consumption. A method to control the grain size would thus be a way to control the electrode efficiency. To alter the catalytically active area, we made changes in the coating process parameters. We found a dependency of the crystal-grain sizes on the choice of ruthenium precursor and processing temperature. The use of ruthenium nitrosyl nitrate resulted in smaller grains than ruthenium chloride and lowering the temperature tended to favour smaller grains. A more radical way would be to create a totally different type of electrode, manufactured in another way than using the 1965 DSA !R recipe. Such new types of electrodes based on, for example, nanowires or nanoimprint lithography, are discussed as future directions.

Bleaching chemicals

sodium chlorate

ruthenium dioxide

electrodes

crystallites

nanowires

microscopy

diffraction

electrocatalytic area

reduced energy consumption

NATURAL SCIENCES

NATURVETENSKAP

Influência da razão combustível-oxidante nas características de óxidos nanoestruturados sintetizados por combustão em solução

Toniolo, Juliano Cantarelli

January 2009

Com o aumento do uso do método de síntese por combustão em solução para obtenção de pós cerâmicos, há uma crescente percepção da necessidade de se entender as características únicas deste processo. Esta tese apresenta uma investigação baseada na obtenção de diferentes pós nanoestruturados: Al2O3-α (alumina), Cr2O3 (crômia), Fe2O3-α (hematita), Fe3O4 (magnetita), NiO (bunsenita) e CoO, Co3O4 (óxidos de cobalto), como opção para futuras aplicações. Estes foram caracterizados via ATD, BET, DRX, MET, MEV, VSM, XPS e FTIR. O foco particular deste trabalho é o estudo da razão combustível-oxidante e sua influência nas características dos materiais resultantes. Outros parâmetros de combustão foram identificados e também devidamente avaliados, tais como: tipo de chama, temperatura, gases gerados e composição química dos reagentes precursores. O cálculo termodinâmico da reação de combustão em solução mostrou que, quando a razão combustível-oxidante aumenta, obtêm-se uma elevação da temperatura de chama adiabática e da quantidade de gás produzida, definindo características do particulado como morfologia, tamanho de cristalito, área superficial e nível de agregação. A formação dos óxidos e metais seguiu um comportamento termodinâmico esperado, conforme energia livre de Gibbs. Menores tamanhos de cristalito foram obtidos sempre na condição deficiente em combustível para todos os sistemas estudados. Já a temperatura foi o principal parâmetro de reação que governou a taxa de crescimento e concorreu com a geração de gases para a formação dos cristalitos em certas condições redutoras. Os resultados deste trabalho melhoraram significativamente o entendimento do efeito da razão combustível-oxidante no comportamento das características físicas dos pós. Esta correlação foi avaliada com intuito de fornecer base de conhecimento para possível aplicação desta tecnologia na otimização ou desenvolvimento de novos sistemas de pós. / With the increasing use of solution combustion synthesis method for powder obtaining, there is a growing realization of the need to understand the unique characteristics of this process. This thesis presents the novel investigation of this technique specifically based upon some nanostructured powders such as α - Al2O3 (alumina), Cr2O3 (eskolite), α - Fe2O3 (hematite), Fe3O4 (magnetite), NiO (bunsenite), and CoO, Co3O4 (cobalt oxides) as a core option for future applications. These were characterized via DTA, BET, XRD, TEM, SEM, VSM, XPS, and FTIR. The particular focus of this work is based on the study of the fuel-to-oxidant ratio influence to the characteristics of the resulting materials. Other combustion parameters were identified and also proper appraised as flame type, temperature, gas generation, and chemical composition of precursor reagents. The thermodynamic calculation of the combustion reaction shows that as fuel-tooxidant ratio increases the amount of gas produced, and adiabatic flame temperature also increases. Powder characteristics as morphology, crystallite size, surface area and aggregation degree are mainly governed by the flame temperature, and generation of gases. The oxide and metals formation followed a thermodynamic behavior as expected, conform to Gibbs free energy. Lower crystallite sizes were always obtained by fuel-lean condition for all studied systems. The temperature was the main reaction parameter controlling the growth rate, while it competed with generation of gases to form crystallites under certain reducing conditions. The outcomes of this work have significantly improved the understanding of the fuelto- oxidant ratio effects on the behavior of the physical characteristics of powders. This correlation has been drawn in order to provide a knowledge basis for possible application of this technology to optimize or develop new powder systems.

Nanomateriais

Combustão em solução

Nanotecnologia

Nanoestruturas

Propriedades termodinâmicas

Ceramic oxides

Solution combustion synthesis

Nano-sized crystallites

Thermodynamic properties

Influência da razão combustível-oxidante nas características de óxidos nanoestruturados sintetizados por combustão em solução

Toniolo, Juliano Cantarelli

January 2009

Com o aumento do uso do método de síntese por combustão em solução para obtenção de pós cerâmicos, há uma crescente percepção da necessidade de se entender as características únicas deste processo. Esta tese apresenta uma investigação baseada na obtenção de diferentes pós nanoestruturados: Al2O3-α (alumina), Cr2O3 (crômia), Fe2O3-α (hematita), Fe3O4 (magnetita), NiO (bunsenita) e CoO, Co3O4 (óxidos de cobalto), como opção para futuras aplicações. Estes foram caracterizados via ATD, BET, DRX, MET, MEV, VSM, XPS e FTIR. O foco particular deste trabalho é o estudo da razão combustível-oxidante e sua influência nas características dos materiais resultantes. Outros parâmetros de combustão foram identificados e também devidamente avaliados, tais como: tipo de chama, temperatura, gases gerados e composição química dos reagentes precursores. O cálculo termodinâmico da reação de combustão em solução mostrou que, quando a razão combustível-oxidante aumenta, obtêm-se uma elevação da temperatura de chama adiabática e da quantidade de gás produzida, definindo características do particulado como morfologia, tamanho de cristalito, área superficial e nível de agregação. A formação dos óxidos e metais seguiu um comportamento termodinâmico esperado, conforme energia livre de Gibbs. Menores tamanhos de cristalito foram obtidos sempre na condição deficiente em combustível para todos os sistemas estudados. Já a temperatura foi o principal parâmetro de reação que governou a taxa de crescimento e concorreu com a geração de gases para a formação dos cristalitos em certas condições redutoras. Os resultados deste trabalho melhoraram significativamente o entendimento do efeito da razão combustível-oxidante no comportamento das características físicas dos pós. Esta correlação foi avaliada com intuito de fornecer base de conhecimento para possível aplicação desta tecnologia na otimização ou desenvolvimento de novos sistemas de pós. / With the increasing use of solution combustion synthesis method for powder obtaining, there is a growing realization of the need to understand the unique characteristics of this process. This thesis presents the novel investigation of this technique specifically based upon some nanostructured powders such as α - Al2O3 (alumina), Cr2O3 (eskolite), α - Fe2O3 (hematite), Fe3O4 (magnetite), NiO (bunsenite), and CoO, Co3O4 (cobalt oxides) as a core option for future applications. These were characterized via DTA, BET, XRD, TEM, SEM, VSM, XPS, and FTIR. The particular focus of this work is based on the study of the fuel-to-oxidant ratio influence to the characteristics of the resulting materials. Other combustion parameters were identified and also proper appraised as flame type, temperature, gas generation, and chemical composition of precursor reagents. The thermodynamic calculation of the combustion reaction shows that as fuel-tooxidant ratio increases the amount of gas produced, and adiabatic flame temperature also increases. Powder characteristics as morphology, crystallite size, surface area and aggregation degree are mainly governed by the flame temperature, and generation of gases. The oxide and metals formation followed a thermodynamic behavior as expected, conform to Gibbs free energy. Lower crystallite sizes were always obtained by fuel-lean condition for all studied systems. The temperature was the main reaction parameter controlling the growth rate, while it competed with generation of gases to form crystallites under certain reducing conditions. The outcomes of this work have significantly improved the understanding of the fuelto- oxidant ratio effects on the behavior of the physical characteristics of powders. This correlation has been drawn in order to provide a knowledge basis for possible application of this technology to optimize or develop new powder systems.

Nanomateriais

Combustão em solução

Nanotecnologia

Nanoestruturas

Propriedades termodinâmicas

Ceramic oxides

Solution combustion synthesis

Nano-sized crystallites

Thermodynamic properties

Influência da razão combustível-oxidante nas características de óxidos nanoestruturados sintetizados por combustão em solução

Toniolo, Juliano Cantarelli

January 2009

Com o aumento do uso do método de síntese por combustão em solução para obtenção de pós cerâmicos, há uma crescente percepção da necessidade de se entender as características únicas deste processo. Esta tese apresenta uma investigação baseada na obtenção de diferentes pós nanoestruturados: Al2O3-α (alumina), Cr2O3 (crômia), Fe2O3-α (hematita), Fe3O4 (magnetita), NiO (bunsenita) e CoO, Co3O4 (óxidos de cobalto), como opção para futuras aplicações. Estes foram caracterizados via ATD, BET, DRX, MET, MEV, VSM, XPS e FTIR. O foco particular deste trabalho é o estudo da razão combustível-oxidante e sua influência nas características dos materiais resultantes. Outros parâmetros de combustão foram identificados e também devidamente avaliados, tais como: tipo de chama, temperatura, gases gerados e composição química dos reagentes precursores. O cálculo termodinâmico da reação de combustão em solução mostrou que, quando a razão combustível-oxidante aumenta, obtêm-se uma elevação da temperatura de chama adiabática e da quantidade de gás produzida, definindo características do particulado como morfologia, tamanho de cristalito, área superficial e nível de agregação. A formação dos óxidos e metais seguiu um comportamento termodinâmico esperado, conforme energia livre de Gibbs. Menores tamanhos de cristalito foram obtidos sempre na condição deficiente em combustível para todos os sistemas estudados. Já a temperatura foi o principal parâmetro de reação que governou a taxa de crescimento e concorreu com a geração de gases para a formação dos cristalitos em certas condições redutoras. Os resultados deste trabalho melhoraram significativamente o entendimento do efeito da razão combustível-oxidante no comportamento das características físicas dos pós. Esta correlação foi avaliada com intuito de fornecer base de conhecimento para possível aplicação desta tecnologia na otimização ou desenvolvimento de novos sistemas de pós. / With the increasing use of solution combustion synthesis method for powder obtaining, there is a growing realization of the need to understand the unique characteristics of this process. This thesis presents the novel investigation of this technique specifically based upon some nanostructured powders such as α - Al2O3 (alumina), Cr2O3 (eskolite), α - Fe2O3 (hematite), Fe3O4 (magnetite), NiO (bunsenite), and CoO, Co3O4 (cobalt oxides) as a core option for future applications. These were characterized via DTA, BET, XRD, TEM, SEM, VSM, XPS, and FTIR. The particular focus of this work is based on the study of the fuel-to-oxidant ratio influence to the characteristics of the resulting materials. Other combustion parameters were identified and also proper appraised as flame type, temperature, gas generation, and chemical composition of precursor reagents. The thermodynamic calculation of the combustion reaction shows that as fuel-tooxidant ratio increases the amount of gas produced, and adiabatic flame temperature also increases. Powder characteristics as morphology, crystallite size, surface area and aggregation degree are mainly governed by the flame temperature, and generation of gases. The oxide and metals formation followed a thermodynamic behavior as expected, conform to Gibbs free energy. Lower crystallite sizes were always obtained by fuel-lean condition for all studied systems. The temperature was the main reaction parameter controlling the growth rate, while it competed with generation of gases to form crystallites under certain reducing conditions. The outcomes of this work have significantly improved the understanding of the fuelto- oxidant ratio effects on the behavior of the physical characteristics of powders. This correlation has been drawn in order to provide a knowledge basis for possible application of this technology to optimize or develop new powder systems.

Nanomateriais

Combustão em solução

Nanotecnologia

Nanoestruturas

Propriedades termodinâmicas

Ceramic oxides

Solution combustion synthesis

Nano-sized crystallites

Thermodynamic properties

Synthesis, Optical And Photoelectrical Investigations On PbS nano-,micro-structures

Pendyala, Naresh Babu

04 1900

The thesis describes the synthesis of PbS nano-, micro-structures by colloidal and hydrothermal techniques. Size and morphology dependent luminescence studies were carried out in detail. Application oriented studies like ion sensing and modulation of luminescence are carried out on colloidal PbS QDs. Photoelectrical studies are carried out on various morphologies of PbS microstructures. We observe the persistent photoconductivity, growth and quenching of photocurrent, and a few novel phenomena in flower shaped PbS microstructures. This work is presented in eight chapters inclusive of summary and directions for future work. CHAPTER 1 provides a brief introduction to optical and photoelectrical properties of semiconductor quantum dots and hydrothermal technique in preparation of quantum structures. A review of PbS nanostructures and its technological applications are discussed. CHAPTER 2 provides the experimental techniques used in this work. First, the synthesis of PbS nano-, micro-structures by various methods, and characterization tools used in this work are briefly presented. CHAPTER 3 deals with the synthesis of PbS quantum dots in poly vinyl alcohol with various precursor concentrations to identify the surface states by temperature dependent photoluminescence (PL) measurements. Average bandgap value calculated from absorption measurements was 2.1 eV. We have observed that high-energy PL bands (>1.3 eV) are due to electron traps (Pb dangling bonds) and low-energy bands (<1 eV) are due to hole traps (S dangling bonds). By capping with thiol compounds (mercaptoethanol-C2 H5OSH), absence of the 1.67 eV band indicates the passivation of Pb dangling bonds. To explain above observed results, we propose a band diagram with distributed shallow to deep states and attributed them to the specific surface related defects (Pb or S). CHAPTER 4 discusses the ion sensing applications of PbS quantum dots. We found that the sulfur related dangling bonds are quite sensitive to different metallic ions (since mercaptoethanol passivates only Pb atoms). Sulfur related PL band (~ 1 eV) have shown an order of magnitude improvement in its intensity for Hg, Ag ions and relatively low enhancement for Zn, Cd ions at 1 µmol concentrations. However Cu quenches the luminescence. An important distinction may have to be made between PbS and Cd related quantum structures. The PbS QDs can distinguish between Cu & Hg, however Cd related QDs couldn’t distinguish between these two ions. Photo-brightening and photo-darkening is an interesting phenomena indicative of photo-induced ionic migration that either helps in enhancing the emission of sulfur related defect emission or degrades the emission properties depending on the ion concentration. This report is the first of its kind in ion sensing applications using PbS QDs. CHAPTER 5 discusses the results of duel beam excitation on trap luminescence of PbS QDs. By using different lasers simultaneously (514 nm and 670 nm), we have observed the reversible luminescence quenching of trap emission. The high-energy PL band (1.67 eV) has double the quenching effect compared to low-energy PL band (1.1 eV). The luminescence quenching mechanism is attributed to the re-emission of the charge carriers from the traps (photo-ionization) due to the simultaneous excitation with the second beam. The dependence of the temperature, the effect of two beam excitation intensities and modulation frequency dependent quenching mechanism are primarily focused in this chapter. The quenching mechanism is considered to be quite useful in the optical modulation devices. CHAPTER 6 discusses the PL results on various morphologies of PbS nano-, microstructures. Interestingly, after protecting the surface with organic ligands such as mercaptoethanol (C2 H5OSH), dendrite structures have shown high-energy bands (~ 1.0 eV) in the PL spectra, which indicate the existence of various quantum confinement regimes in different branches of dendrites. The anomalous temperature dependent behavior of PL intensity is attributed to the size distribution. CHAPTER 7 discusses the results of photoconductivity measurements on various morphologies of PbS nano-, micro-structures. Flower shaped structures have shown persistent photoconductivity (PPC). This observed PPC is attributed to the presence of potential barriers, which are created by the different confinement regimes or due to the lattice relaxation, which occurs due to the carrier trapping at surfaces. In PPC, the estimated time constants of both build up and decay transients using the stretched exponentials are of the order of few tens of seconds. In PPC measurements, we observe the PC quenching below 40 K and growth above this temperature. PC quenching is attributed to the transfer of photo-excited carriers to a metastable state. The presence of metastable state is supported by the dark conductivity measurements in flower shaped structures. CHAPTER 8 presents the summary and directions for the future work.

Lead Sulfide - Nano technology

Lead Sulfide - Synthesis

Lead Sulfide Nanostructures

Lead Sulfide Quantum Dots - Synthesis

Lead Sulfide Quantum Dots - Ion Sensing

PbS Nanoparticles

PbS Quantum Dots

Poly Vinyl Alcohol

PbS Nanostructures

PbS Nano-, Micro-structures

PbS Dendrite Structures

Nanotechnology