Mixed metal oxide - noble metal catalysts for total oxidation of volatile organic compounds and carbon monoxide

Ferrandon, Magali

January 2001

CO, volatile organic compounds, and polyaromatics areubiquitous air pollutants that give rise to deleterious healthand environmental effects. Such compounds are emitted, forinstance, by the combustion of wood, particularly fromsmall-scale heating appliances. Total catalytic oxidation isconsidered to be an effective approach in controlling theseemissions, however, some problems remain such as thenon-availability of catalysts with low-cost, high activity andstability in prevailing conditions. Hence, this thesis aims atthe development of oxidation catalysts and improvedunderstanding of their behaviour. The catalytic activity was evaluated for the oxidation of amixture of CO, naphthalene (or ethylene), and methane inpresence of carbon dioxide, water, oxygen and nitrogen. Variouscharacterisation techniques, including Temperature-ProgrammedReduction and Oxidation, BET-Surface Area Analysis, X-RayDiffraction, X-Ray Photoelectron Spectroscopy, RamanSpectroscopy and Scanning and Transmission Electron Microscopywere used. In the first part of this thesis, catalysts based on metaloxides (MnOx, CuO) and/or a low amount of noble metals (Pt, Pd)supported on alumina washcoat were selected. It was shown thatPt and Pd possessed a superior catalytic activity to that ofCuO and MnOxfor the oxidation of CO, C10H8and C2H4, while for the oxidation of CH4, CuO was largely more active than noble metals,and MnOxas active as Pd and Pt. Some mixed metaloxide-noble metal catalysts showed decreased activity comparedto that of noble metals, however, a higher noble metal loadingor a successive impregnation with noble metals led to positivesynergetic effects for oxidation. Deactivation of the catalysts by thermal damage and sulphurpoisoning is addressed in the second part of the dissertation.An alumina washcoat was found to be well anchored to themetallic support after thermal treatment at 900°C due tothe growth of alumina whiskers. The sintering of the washcoatwas accelerated after high temperature treatments in thepresence of metal catalysts. In addition, alumina was found toreact with CuO, particularly in presence of noble metals at900°C, to form inactive CuAl2O4. However, MnOxcatalyst benefits from the more active Mn3O4phase at high temperature, which makes it asuitable active catalyst for the difficult oxidation of CH4. Pt sintering was delayed when mixed with CuO,thus giving more thermally resistant catalyst. The mixed metaloxide-noble metal catalysts showed higher activity afterpre-sulphation of the catalysts with 1000 ppm SO2in air at 600°C or during activitymeasurement in presence of 20 ppm SO2in the gas mixture, compared to single componentcatalysts. In some cases, the activities of the mixed catalystswere promoted by pre-sulphation due to the presence of sulphatespecies. Thermal stabilisation of the catalytic componentsand thealumina by promotion of La in the washcoat is discussed in thethird section. The stabilising effect of La at high temperatureis also compared to that of Ce added in the catalysts for otherpurposes. Due to its better dispersion, La contributed to thethermal stabilisation of the alumina washcoat and its activecomponents to a higher extent than Ce did. La provided a betterdispersion and a higher saturation of metal oxides in thealumina support, and at the same time stabilised the activityof the catalysts by preventing undesirable solid-phasereactions between metal oxide and alumina. In addition, La wasfound to enhance the dispersion and the oxygen mobility of CeO2. Cu-Ce interactions were found to promotesubstantially the CO oxidation due to an increase of thestability and reducibility of Cu species. Synergetic effectswere also found between Ce and La in the washcoat of CuO-Ptcatalyst, which facilitated the formation of reduced Pt and CeO2, thus enhancing significantly the catalyticactivity compared to that of a Pt only catalyst. The last part was an attempt to demonstrate the potential ofa catalyst equipped with a pre-heating device in a full-scalewood-fired boiler for minimising the high emissions during thestart-up phase. During the first ten minutes of the burningcycle a significant reduction of CO and hydrocarbons wereachieved. <b>Keywords</b>: wood combustion, catalysts, total oxidation,manganese, copper, platinum, palladium, lanthanum, cerium, CO,VOC, methane, deactivation, thermal stability, sulphurdioxide.

wood combustion

catalysts

total oxidation

manganese

copper

platinum

palladium

lanthanum

cerium

CO

VOC

methane

deactivation

thermal stability

sulphur dioxide

Mixed metal oxide - noble metal catalysts for total oxidation of volatile organic compounds and carbon monoxide

Ferrandon, Magali

January 2001

<p>CO, volatile organic compounds, and polyaromatics areubiquitous air pollutants that give rise to deleterious healthand environmental effects. Such compounds are emitted, forinstance, by the combustion of wood, particularly fromsmall-scale heating appliances. Total catalytic oxidation isconsidered to be an effective approach in controlling theseemissions, however, some problems remain such as thenon-availability of catalysts with low-cost, high activity andstability in prevailing conditions. Hence, this thesis aims atthe development of oxidation catalysts and improvedunderstanding of their behaviour.</p><p>The catalytic activity was evaluated for the oxidation of amixture of CO, naphthalene (or ethylene), and methane inpresence of carbon dioxide, water, oxygen and nitrogen. Variouscharacterisation techniques, including Temperature-ProgrammedReduction and Oxidation, BET-Surface Area Analysis, X-RayDiffraction, X-Ray Photoelectron Spectroscopy, RamanSpectroscopy and Scanning and Transmission Electron Microscopywere used.</p><p>In the first part of this thesis, catalysts based on metaloxides (MnO_x, CuO) and/or a low amount of noble metals (Pt, Pd)supported on alumina washcoat were selected. It was shown thatPt and Pd possessed a superior catalytic activity to that ofCuO and MnO_xfor the oxidation of CO, C₁₀H₈and C₂H₄, while for the oxidation of CH₄, CuO was largely more active than noble metals,and MnO_xas active as Pd and Pt. Some mixed metaloxide-noble metal catalysts showed decreased activity comparedto that of noble metals, however, a higher noble metal loadingor a successive impregnation with noble metals led to positivesynergetic effects for oxidation.</p><p>Deactivation of the catalysts by thermal damage and sulphurpoisoning is addressed in the second part of the dissertation.An alumina washcoat was found to be well anchored to themetallic support after thermal treatment at 900°C due tothe growth of alumina whiskers. The sintering of the washcoatwas accelerated after high temperature treatments in thepresence of metal catalysts. In addition, alumina was found toreact with CuO, particularly in presence of noble metals at900°C, to form inactive CuAl₂O₄. However, MnO_xcatalyst benefits from the more active Mn₃O₄phase at high temperature, which makes it asuitable active catalyst for the difficult oxidation of CH₄. Pt sintering was delayed when mixed with CuO,thus giving more thermally resistant catalyst. The mixed metaloxide-noble metal catalysts showed higher activity afterpre-sulphation of the catalysts with 1000 ppm SO₂in air at 600°C or during activitymeasurement in presence of 20 ppm SO₂in the gas mixture, compared to single componentcatalysts. In some cases, the activities of the mixed catalystswere promoted by pre-sulphation due to the presence of sulphatespecies.</p><p>Thermal stabilisation of the catalytic componentsand thealumina by promotion of La in the washcoat is discussed in thethird section. The stabilising effect of La at high temperatureis also compared to that of Ce added in the catalysts for otherpurposes. Due to its better dispersion, La contributed to thethermal stabilisation of the alumina washcoat and its activecomponents to a higher extent than Ce did. La provided a betterdispersion and a higher saturation of metal oxides in thealumina support, and at the same time stabilised the activityof the catalysts by preventing undesirable solid-phasereactions between metal oxide and alumina. In addition, La wasfound to enhance the dispersion and the oxygen mobility of CeO₂. Cu-Ce interactions were found to promotesubstantially the CO oxidation due to an increase of thestability and reducibility of Cu species. Synergetic effectswere also found between Ce and La in the washcoat of CuO-Ptcatalyst, which facilitated the formation of reduced Pt and CeO₂, thus enhancing significantly the catalyticactivity compared to that of a Pt only catalyst.</p><p>The last part was an attempt to demonstrate the potential ofa catalyst equipped with a pre-heating device in a full-scalewood-fired boiler for minimising the high emissions during thestart-up phase. During the first ten minutes of the burningcycle a significant reduction of CO and hydrocarbons wereachieved.</p><p><b>Keywords</b>: wood combustion, catalysts, total oxidation,manganese, copper, platinum, palladium, lanthanum, cerium, CO,VOC, methane, deactivation, thermal stability, sulphurdioxide.</p>

wood combustion

catalysts

total oxidation

manganese

copper

platinum

palladium

lanthanum

cerium

CO

VOC

methane

deactivation

thermal stability

sulphur dioxide

Influence of SO2 fumigation on growth, photosynthesis, lipoxygenase and peroxidase activities of soybean (Glycine max), in open-top chambers / Susan Lindeque

Lindeque, Susan

January 2012

Air pollutant exposure poses a health risk to humans and impacts negatively on agriculture. High levels of air pollution resulted in extensive crop damage and yield reduction in Europe and USA. The Highveld region in South Africa, a very important area for maize and soya production, has already been declared an air pollution hot spot, with SO2 being the most concerning air pollutant. Most of the SO2 over the Highveld originates from the burning of coal for power generation. Developing countries, such as South Africa, are highly dependent on agriculture for food security and high levels of air pollution pose serious risks to the agricultural industry. Currently very little information is available on the effects of air pollution on crop production in South Africa. This study aimed to establish exposure-response relationship for SO2 on soybean and the quantification thereof on the morphological, physiological and biochemical characteristics. Two soybean cultivars were used, namely: LS 6164 and PAN 1666. The plants were fumigated for 7 hours, 7 days a week with 0 (carbon filtered control; CF), 25, 75 and 150 ppb SO2. The effect of SO2 was investigated on the growth, photosynthetic capabilities, photosynthetic gas exchange, peroxidase activity and lipoxygenase activity of the cultivars. Foliar injuries and interveinal chlorosis were visible with increasing levels of SO2 as well as a decrease in biomass accumulation, especially in root biomass; a more prominent feature of LS 6164. The number of nodules of both cultivars decreased insignificantly as the levels of SO2 increased. The number of pods per plant and the average weight of 30 seeds indicated a downward trend with an increase in SO2 concentration. The chlorophyll content of PAN 1666 was lower compared to LS 6164. PAN 1666 had the largest reduction in stomatal conductance at 150 ppb SO2 fumigation. The photosynthetic vitality index indicated that LS 6164 was more sensitive to SO2 inhibition from 25 ppb SO2 and higher, whereas PAN 1666 mostly became sensitive to SO2 from 75 ppb SO2. A decrease in the ability to absorb light energy, the trapping of excitation energy to transfer electrons beyond QA-, and the reduction of end electron acceptors all contributed to the decline in the vitality index. Sulphur content increased significantly in the 75 ppb and 150 ppb treatments of both cultivars. Induced peroxidase and lipoxygenase activity was seen in both cultivars, especially at higher concentrations of SO2 treatments. PAN 1666 had a higher rate of peroxidase and lipoxygenase activity compared to LS 6164. The implication for SO2 on crop production in the highly industrial Highveld area was demonstrated to be potentially of great concern. The dose-response relationships plotted for OJIP parameters emphasized that SO2 is an inhibitor of photosynthesis and phytotoxic of nature. Both cultivars experienced limitations from 75 ppb, especially at the 150 ppb SO2 concentration. From these results it appears that PAN 1666 is more adapted to SO2 compared to LS 6164 and levels of 75 ppb SO2 and higher become toxic to these plants. / Thesis (Master of Environmental Sciences)--North-West University, Potchefstroom Campus, 2013

Air pollution

Biomass

Chlorophyll a fluorescence

Chlorophyll content

Gas exchange

Glycine max

Lipoxygenase

Peroxidase

Soya

Sulphur dioxide

Stomatal conductance

Sulphur content

Influence of SO2 fumigation on growth, photosynthesis, lipoxygenase and peroxidase activities of soybean (Glycine max), in open-top chambers / Susan Lindeque

Lindeque, Susan

January 2012

Air pollutant exposure poses a health risk to humans and impacts negatively on agriculture. High levels of air pollution resulted in extensive crop damage and yield reduction in Europe and USA. The Highveld region in South Africa, a very important area for maize and soya production, has already been declared an air pollution hot spot, with SO2 being the most concerning air pollutant. Most of the SO2 over the Highveld originates from the burning of coal for power generation. Developing countries, such as South Africa, are highly dependent on agriculture for food security and high levels of air pollution pose serious risks to the agricultural industry. Currently very little information is available on the effects of air pollution on crop production in South Africa. This study aimed to establish exposure-response relationship for SO2 on soybean and the quantification thereof on the morphological, physiological and biochemical characteristics. Two soybean cultivars were used, namely: LS 6164 and PAN 1666. The plants were fumigated for 7 hours, 7 days a week with 0 (carbon filtered control; CF), 25, 75 and 150 ppb SO2. The effect of SO2 was investigated on the growth, photosynthetic capabilities, photosynthetic gas exchange, peroxidase activity and lipoxygenase activity of the cultivars. Foliar injuries and interveinal chlorosis were visible with increasing levels of SO2 as well as a decrease in biomass accumulation, especially in root biomass; a more prominent feature of LS 6164. The number of nodules of both cultivars decreased insignificantly as the levels of SO2 increased. The number of pods per plant and the average weight of 30 seeds indicated a downward trend with an increase in SO2 concentration. The chlorophyll content of PAN 1666 was lower compared to LS 6164. PAN 1666 had the largest reduction in stomatal conductance at 150 ppb SO2 fumigation. The photosynthetic vitality index indicated that LS 6164 was more sensitive to SO2 inhibition from 25 ppb SO2 and higher, whereas PAN 1666 mostly became sensitive to SO2 from 75 ppb SO2. A decrease in the ability to absorb light energy, the trapping of excitation energy to transfer electrons beyond QA-, and the reduction of end electron acceptors all contributed to the decline in the vitality index. Sulphur content increased significantly in the 75 ppb and 150 ppb treatments of both cultivars. Induced peroxidase and lipoxygenase activity was seen in both cultivars, especially at higher concentrations of SO2 treatments. PAN 1666 had a higher rate of peroxidase and lipoxygenase activity compared to LS 6164. The implication for SO2 on crop production in the highly industrial Highveld area was demonstrated to be potentially of great concern. The dose-response relationships plotted for OJIP parameters emphasized that SO2 is an inhibitor of photosynthesis and phytotoxic of nature. Both cultivars experienced limitations from 75 ppb, especially at the 150 ppb SO2 concentration. From these results it appears that PAN 1666 is more adapted to SO2 compared to LS 6164 and levels of 75 ppb SO2 and higher become toxic to these plants. / Thesis (Master of Environmental Sciences)--North-West University, Potchefstroom Campus, 2013

Air pollution

Biomass

Chlorophyll a fluorescence

Chlorophyll content

Gas exchange

Glycine max

Lipoxygenase

Peroxidase

Soya

Sulphur dioxide

Stomatal conductance

Sulphur content

Volatile sulfur compounds in coastal acid sulfate soils, northern N.S.W.

Kinsela, Andrew Stephen, School of Biological, Earth & Environmental Sciences, UNSW

January 2007

The cycling of biogenic volatile sulfur compounds (VSCs) within marine and terrestrial ecosystems has been shown to play an integral role in atmospheric chemistry; by influencing global climate change through the creation of cloud condensation nuclei and controlling acid-base chemistry; as well as influencing sediment chemistry including the interactions with trace metals, particularly regarding iron sulfide formation. Despite this, the examination of VSCs within Australian coastal acid sulfate soils (ASS) is an unexplored area of research. As ASS in Australia occupy an area in excess of 9 M ha, there is a clear need for a greater understanding of the cycling of these compounds within such systems. This thesis looks at the concentrations of several VSCs within agricultural and undisturbed ASS on the east coast of Australia. Initial measurements of sulfur dioxide (SO2) were made using passive diffusion samplers, which were followed by two detailed field-based studies looking at the concentrations and fluxes of both SO2 and hydrogen sulfide (H2S) using flux-gradient micrometeorological techniques. These novel results indicated that this agricultural ASS was a substantial source of atmospheric H2S (0.036-0.056 gSm-2yr-1), and SO2 (0.095-0.31 gSm-2yr-1), with flux values equating to many other salt- and freshwater marshes and swamps. The flux data also suggested that the ASS could be a continual source of H2S which is photo-oxidised during the daytime to SO2. Measurements of both compounds showed separate, inverse correlations to temperature and moisture meteorological parameters indicating possible contributing and / or causal release factors. Further identification of these and other VSCs within ASS samplers was undertaken in the laboratory using gas chromatography in combination with solid-phase microextraction. Although SO2 and H2S were not discovered within the headspace samples, two other VSCs important in atmospheric sulfur cycling and trace metal geochemistry were quantified; dimethylsulfide (DMS; &gt 300??g/L) and ethanethiol (ESH &gt 4??g/L). The measurements of H2S, DMS and ESH are the first quantifications with Australian ASS, and they may be important for refining regional or local atmospheric sulfur budgets, as well as interpreting previous SO2 emissions from ASS. Ultimately this thesis further enhances our understanding of the cycling of VSCs within acid sulfate systems.

Sulphur dioxide -- Analysis.

Hydrogen sulphide -- Analysis.

An evaluation of sulphur dioxide fume levels and the prevalence of darkroom disease symptoms amongst radiology workers in Namibia

Damases, Christine

January 2006

Thesis (M.Tech.: Radiography)-Dept. of Radiography, Durban University of Technology, 2006 xi, 86 leaves, Annexures A-Q / The study will determine the sulphur dioxide (SO2) levels in the x-ray department and evaluate it’s effects on the health of the radiology workers. The aim of the study is to mainly create awareness of occupational hazards posed by processing chemistry to radiology workers.

Radiography--Namibia

Radiography--Equipment and supplies

Sulphur dioxide--Physiological effect

Industrial hygiene

Industrial safety

Investigating the impact of sulphur dioxide on Brettanomyces bruxellensis at a molecular and cellular level

Duckitt, Edward

03 1900

Thesis (MSc)--Stellenbosch University, 2012. / ENGLISH ABSTRACT: The yeast Brettanomyces was isolated from beer in 1904 and associated with wine thereafter. A sporulating form, Dekkera, was discovered later. Brettanomyces bruxellensis produces high levels of volatile phenol off-flavours in wine. Sulphur dioxide (SO2) is the most widely used chemical preservative in wine. Yeasts have several mechanisms to cope with the SO2, namely Ssu1p, a membrane bound SO2 transporter; sulphite reduction, sulphite oxidation and acetaldehyde production. In unfavourable environmental conditions, certain yeasts can enter a viable-but-non-culturable (VBNC) state which is characterised by reduced metabolic rate, inability to reproduce on solid media and a reduction of cell size. VBNC can be triggered by chemical stress such as high SO2 levels. The objectives of this study were to examine the SO2 tolerance of B. bruxellensis and Saccharomyces cerevisiae, to quantify their rates of SO2 accumulation and efflux, determine the effect of SO2 on their energy metabolism and investigate if B. bruxellensis possesses an orthologue to S. cerevisiae SSU1. In this study, the identity of a number of Brettanomyces/Dekkera strains was confirmed using 5.8S rDNA-ITS RFLP analysis and DNA sequencing. Sporulation assays were used to confirm whether these strains belonged to the Dekkera or Brettanomyces genus. A method to accurately quantify SO2 in laboratory conditions was optimised. Molecular SO2 tolerance was tested by spotting fresh yeast cultures on media with SO2 and/or ethanol. Tolerance to SO2 and/or ethanol showed highly strain dependent results with S. cerevisiae showing the highest tolerance levels while B. bruxellensis tolerated SO2 and ethanol poorly but certain strains grew well with only SO2. The SO2 accumulation and efflux rates of 3 S. cerevisiae strains and 3 B. bruxellensis strains were determined. It was shown that the S. cerevisiae strains followed the same trends as previously found in literature whereas B. bruxellensis strains showed similar trends but displayed highly variable strain-dependent results. B. bruxellensis CB63 and S. cerevisiae VIN13 were investigated for their response to SO2 in two different media, TA and SWM, over a 48-hour and 32-day period respectively. Acetic acid, acetaldehyde, D-glucose, D-fructose (only in SWM) and ethanol (only in TA) were regularly monitored over the time course of each experiment. SO2 had the greatest impact on B. bruxellensis with decreased rates of glucose consumption and ethanol production as well as increased acetic acid. Acetaldehyde peaked shortly after SO2 addition with the subsequent restarting of sugar consumption for certain samples. This suggests that sufficient acetaldehyde was produced to bind free SO2 to reduce SO2 stress. Volatile phenols were quantified for day 32 of the SWM experiment. An increase of 4-ethyl guaiacol was correlated to higher molecular SO2 levels. SO2 negatively affected both yeasts energy metabolism, forcing the yeasts metabolism to adapt to ensure survival. In general, SO2 was shown to have a negative impact on all aspects of a yeasts growth and metabolism and that SO2 tolerance is highly strain dependent and a far more complicated characteristic than currently understood. / AFRIKAANSE OPSOMMING: Die gis Brettanomyces is in 1904 uit bier geïsoleer en daarna met wyn geassosieer. 'n sporulerende vorm, Dekkera, is later ontdek. Brettanomyces bruxellensis produseer hoë vlakke van vlugtige fenol afgeure in wyn. Swaweldioksied (SO2) is die mees gebruikte chemiese preserveermiddel in wyn. Giste het verskeie meganismes om SO2 te hanteer, naamlik Ssu1p, 'n membraan-gebonde SO2 transporter, sulfietvermindering, sulfiet-oksidasie en asetaldehiedproduksie. In ongunstige omgewingstoestande kan sekere giste 'n lewensvatbare, maar nie-kultiveerbare (LMNK)-toestand aanneem wat gekenmerk word deur verlaagde metaboliese tempo, onvermoë om voort te plant op soliede media en 'n vermindering van die selgrootte. LMNK kan veroorsaak word deur chemiese stres, soos hoë SO2-vlak. Die doelwitte van hierdie studie was om die SO2 -bestandheid van B. bruxellensis en Saccharomyces cerevisiae te ondersoek, hul spoed van SO2 -opneming/akkumulasie en -uitskeiding te kwantifiseer, die invloed van SO2 op energiemetabolisme te bepaal en te ondersoek of B. bruxellensis oor ‘n soortgelyke geen as die S. cerevisiae SSU1 beskik. In hierdie studie is die identiteit van 'n aantal Brettanomyces/Dekkera-stamme bevestig deur 5.8S rDNA-ITS RFLP-analise en DNA-opeenvolging te gebruik. Sporulasietoetse is gebruik om te bevestig of hierdie stamme aan die genus Dekkera of Brettanomyces behoort. 'n Metode om SO2 onder laboratoriumtoestande akkuraat te kwantifiseer, is geoptimiseer. Molekulêre SO2- bestandheid is getoets deur vars giskulture op media met SO2 en/of etanol te groei. Bestandheid teen SO2 en/of etanol het stam-afhanklike resultate getoon, S. cerevisiae wat die hoogste toleransievlakke getoon het, terwyl B. bruxellensis SO2 en etanol swak tolereer, maar sekere stamme het goed gegroei met slegs SO2. Die SO2-akkumulasie en -uitskeidingtempo van 3 S. cerevisiae-rasse en 3 B. bruxellensis-stamme is bepaal. Daar is gevind dat die S. cerevisiae-rasse dieselfde tendens soos voorheen in die literatuur beskryf, gevolg het, terwyl B. bruxellensis-stamme soortgelyke tendense getoon het,maar hoogs veranderlike stamafhanklike resultate vertoon. B. bruxellensis CB63 en S. cerevisiae VIN13 is ondersoek vir hul reaksie tot SO2 in twee verskillende media, TA en SWM, oor 'n tydperk van 48-uur en 32-dae onderskeidelik. Asynsuur, asetaldehied, D-glukose, D-fruktose (slegs in SWM) en etanol (slegs in TA) is gereeld gemoniteer oor die verloop van elke eksperiment. SO2 het die grootste impak op B. bruxellensis met ‘n verlaagde tempo van glukoseverbruik en etanolproduksie, sowel as verhoogde asynsuur. ‘n Asetaldehiedhoogtepunt is bereik kort na die SO2-byvoeging met die daaropvolgende hervatting van suiker wat vir sekere monsters gebruik is. Dit dui daarop dat voldoende asetaldehied geproduseer is om vry SO2 te bind om SO2-stres te verminder. Vlugtige fenole is op dag 32 van die SWM-eksperiment gekwantifiseer. 'n Toename van 4-etiel-guajakol korreleer met hoër molekulêre SO2-vlakke. SO2 het beide giste se energiemetabolisme negatief beïnvloed, wat die gis dwing om sy metabolisme aan te pas om oorlewing te verseker. Oor die algemeen het SO2 'n negatiewe impak op alle aspekte van giste se groei en metabolisme, en SO2-bestandheid is hoogs stam–afhanklik. Dit is ook 'n baie meer ingewikkelde kenmerk as wat tans verstaan word.

Brettanomyces bruxellensis

Wine spoilage

Sulphur dioxide

Stress response

Wine and wine making

Wine microbiology

Dissertations -- Wine biotechnology

Theses -- Wine biotechnology

Efeito da concentração de SO2 nas reações de calcinação e sulfatação de calcários em reator de leito fluidizado / Effect of the concentration of S02 in the reactions of calcination and sulfatation in a fluidized bed reactor

Julio Edgardo Lindo Samaniego

21 November 2003

Foi realizado um estudo sobre o efeito das concentrações de SO2 na sua absorção por calcários em fornalhas de leito fluidizado. Para observar a influência do SO2 sobre os diferentes parâmetros físicos e químicos do processo, foram criadas atmosferas compostas por quatro concentrações diferentes de SO2, que foram de 500, 1.000, 2.000 e 4.000 ppm. Utilizou-se ainda dois tipos de calcários, o Dolomítico-DP e o Calcítico-CI. O leito fluidizado borbulhante utilizado, possuía 160 mm de diâmetro interno e foi fluidizado com ar à temperatura de 850ºC, contendo SO2 na concentração desejada. Como material do leito foi utilizada areia de quartzo (99,9%), com diâmetro de 385 &#956m e aproximadamente 3,0 Kg de massa. O calcário foi adicionado em bateladas de 50 g com o reator já pré-aquecido, enquanto as variações das concentrações dos gases SO2, CO2, CO e O2 e suas descargas foram monitoradas continuamente na saída do ciclone que era utilizado para retenção do particulado fino. Para adquirir esses dados foi desenvolvido um programa em LabView. O modelo matemático escolhido possibilitou a determinação da conversão, da taxa de conversão e do coeficiente global de taxa de reação para todas as condições testadas. / A study of the effect of the concentrations of SO2 in its absorption by limestones in fluidized bed furnaces was conducted. For the determination of the SO2 influence on the different physical and chemical parameters of process, such as calcinations and sulfatation four different atmospheres were used in the reator with concentrations of SO2 of 500, 1.000, 2.000 and 4.000 ppm. Two types of limestones were used : Dolomitico-DP and Calcitico-CI. The bench scale bubbling fluidized bed reactor had a 160 mm internal diameter and was fluidized with air at 850ºC containing the required concentration of SO2. Bed material was quartz sand (99,9%), with 385 &#956m diameter and approximately 3 Kg of mass. The limestone was introduced in samples of 50 g, in the reactor previously stabilized, and the concentration of the gases SO2, CO2, CO and O2 and their discharges in the reactor exit were continually monitored. For the recording of this parameters a data acquisition program in LabView was developed. A mathematical model was used to allow the determination of the conversion, the conversion rate and the global coefficient of reaction rate for all the tested conditions.

Absorção de enxofre

Calcário

Dióxido de enxofre

Leito fluidizado

Reator de leito fluidizado

Fluidized bed

Fluidized bed reactor

Limestone

Sulphur absorption

Sulphur dioxide

Snížení emisí SO2 ve spalinách z fluidního kotle / Reducing emissions of SO2 in the flue gas from the fluidized bed boiler

Tesař, Jan

January 2016

Aim of this thesis is to design a technology of a flue gas desulphurization of fluidized bed boiler. Currently, the state of technology is not able to provide flue gas desulphurisation to required level. For this reason it is necessary to build additional device for the desulphurisation. Theoretical part of the thesis deals with the emission limits of sulphur dioxide, available methods of desulphurization and sorbents suitable for the desulfurization. In practical part conditioned dry sorption method is chosen for the specified source, technological and structural design for suggested desulphurization technology including design of all device is proposed. The thesis also includes a technology design and a 3D model.

Pt and Au as electrocatalysts for various electrochemical reactions / Marthinus Hendrik Steyn

Steyn, Marthinus Hendrik

January 2015

In this study the focus was on the electrochemical techniques and aspects behind the establishment of the better catalyst (platinum or gold) for the sulphur dioxide oxidation reaction (SDOR). One of the primary issues regarding the SDOR is the catalyst material, thus the comparative investigation of the performance of platinum and gold in the SDOR, as found in this study. Ultimately, the SDOR could lead to an effective way of producing hydrogen gas, which is an excellent energy carrier. The electrochemical application of the oxygen reduction reaction (ORR) and ethanol oxidation reaction (EOR) is an integral part of the catalytic process of water electrolysis, and by using fuel cell technology, it becomes even more relevant to this study and can therefore be used as a control, guide and introduction to the techniques required for electrochemical investigation of catalyst effectiveness. Subsequently, the EOR as well as the ORR was used as introduction into the different electrochemical quantification and qualification techniques used in the electrochemical analyses of the SDOR. Considering the ORR, gold showed no viable activity in acidic medium, contrarily in alkaline medium, it showed good competition to platinum. Gold also lacked activity towards the EOR in acidic medium compared to platinum, with platinum the best catalyst in both acidic and alkaline media. Ultimately, platinum was established to be the material with better activity for the ORR with gold a good competitor in alkaline medium, and platinum the better catalyst for the EOR in both acidic and alkaline media. With the main focus of this study being the SDOR, gold proved to be the best catalyst in salt and gaseous forms of SO2 administration compared to platinum when the onset potential, maximum current density, Tafel slope and number of electrons transferred are taken into consideration. The onset potential was determined as 0.52 V vs. NHE for both platinum and gold using SO2 gas and 0.54 V and 0.5 V for gold and platinum respectively, using Na2SO3 salt. The maximum current density using gaseous SO2 for platinum at 0 RPM was 400 mA/cm2 with a Tafel slope of 891 mV/decade whereas gold had a maximum current density of 300 mA/cm2 and a Tafel slope of 378 mV/decade. Using Na2SO3 salt, the maximum current density of gold was 25 mA/cm2 with a Tafel slope of 59 mV/decade whereas platinum only achieved 18 mA/cm2 with a Tafel slope of 172 mV/decade. Concerning the number of electrons transferred, gold achieves a transfer of 2 while platinum only 1 for both SO2 gas and Na2SO3 salt. Taking all these summarised determinations into account, gold was established to be a very competitive catalyst material for the SDOR, compared to platinum. / MSc (Chemistry), North-West University, Potchefstroom Campus, 2015

Polycrystalline

Gold

Platinum

Fuel Cell

Ethanol Oxidation Reaction

Sulphur Dioxide Oxidation Reaction

Oxygen Reduction Reaction

Tafel

Koutecký-Levich

Levich

Electrochemistry

Electrode

Sulphur Depolarised Electrolyser