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Enhanced molybdate conversion coatingsWalker, Dane E. January 2013 (has links)
The replacement of chromate conversion coatings for zinc coated components has been necessitated by the materials finishing industries due to the inherent toxicity issues with Cr(VI) and the legislative enforcement of WEEE and ELV Directives by the European Union. Current replacements are based on non-chromate , Cr(III) systems, these may be perceived by some to be problematic as they still contain chromium . Molybdate based conversion coatings have long been viewed by many researchers to be a viable non-chromium alternative due to their low toxicity. An extensive literature review of the research carried out in the last 20 years was carried out, highlighting areas of interest for improving the corrosion resistance of the coatings studied. These were, primarily, the synergesis that exists with molybdate and phosphate compounds for corrosion resistance and the incorporation of nanoparticle silica into treatment solution. Also discovered was the importance of the acid used to adjust treatment solution pH, immersion time, oxidising agent additions and the incorporation of rare earth metal species. Silicate sealant layers were also highlighted as a post treatment. Molybdate-based coatings were formed on commercial electrodeposited acid zinc surfaces. Many treatment conditions were investigated, and initially performance analysed using DC Linear Polarisation Resistance (LPR) trials. Subsequently, the highest performing coatings were subjected to the more aggressive, industry standard, ASTM B 117 Neutral Salt Spray (NSS) corrosion test. The highest performing molybdate coatings were found to have an average LPR of ~ 9 000 Ω. cm2, in contrast to ~ 12 000 Ω. cm2 for the Cr(VI) based reference. NSS results were amongst the highest performing for molybdate based coatings documented, at 24 h until 5% white rust, however remained inferior to Cr(VI) coatings, which lasted 120 h. The highest performing coatings were characterised using FEG-SEM, Cryofracture EDXA and site specific AES. These techniques revealed that the enhanced molybdate coatings had a columnar structure that was around 300 nm thick, with pores that appeared to expose the substrate. AES showed this type of coating to have a mixed Mo, P and Zn oxide surface. Corrosion initiation was also studied; this can be thought of as an investigation to determine the point(s) of weakness or the mechanism that causes coating failure. Coatings were immersed in 5 % wt/ vol NaCl(aq) until they showed any surface change. Initial signs of corrosion were deemed to be any appearance of pitting or discolouration of the film, not a voluminous corrosion product. Untreated Zn, Cr(VI) and simple molybdate coatings were studied as well as enhanced molybdate coatings. There were clear differences in the way the coatings behaved at the onset of corrosion. Cr(VI) coatings delaminated, leaving an area of decreased Cr concentration. The enhanced molybdate coatings failed by the appearance of localised pores of ~ 70 µm in diameter. Substrate exposure was indisputably the reason for coating failure in chloride environments. In light of the work carried out in the present thesis the outlook for the use of molybdate as a potential replacement for chromate for the conversion coating of electrodeposited zinc surfaces is a positive one.
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Modelling the Photoreduction of A Chromium (VI) Pigment in Alfredo Ramos Martínez’s Mural Flower VendorsHolzer, Gillian G 01 January 2019 (has links)
One of the most stunning works of art on the Scripps College campus is the mural Flower Vendors(1946). The artist,Alfredo Ramos Martínez, an influential figure in Mexican Modernism, executed the work using a variety of traditional and non-traditional techniques. Prior analysis of the work indicated the use of a wax emulsion medium and established the range of pigments used. Ramos Martínez’s use of lead chromate (chrome yellow, Pb(CrO4)) was unusual in wall painting, and the pigment itself has been shown to photodegrade and darken over time in oil paintings, due to the reduction of Cr(VI) to Cr(III). The Pb(CrO4) in Flower Vendorsdoes not appear to have darkened, raising questions about the stability of lead chromate in a wax-emulsion medium relative to that of oil-based mediums. To better understand the behavior of lead chromate in wax-based mediums, a historical synthesis of lead chromate was recreated, and the pigment was suspended in four different binder matrices: a wax-water emulsion, refined linseed oil, cold-pressed linseed oil, and poppy oil. Each of these paint-binder mixtures wasaged beneath full-spectrum 6500 K LED lights. The relative darkening of the pigments was measured using UV-Vis reflectance colorimetry, and comparisons were made between the mediums.
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Critical potential and oxygen evolution of the chlorate anodeNylén, Linda January 2006 (has links)
<p>In the chlorate process, natural convection arises thanks to the hydrogen evolving cathode. This increases the mass transport of the different species in the chlorate electrolyte. There is a strong connection between mass transport and the kinetics of the electrode reactions. A better knowledge about these phenomena and their interactions is desirable in order to understand e.g. the reasons for deactivation of anode coatings and what process conditions give the longest lifetime and the highest efficiency.</p><p>One of the aims of his work was to understand how the chlorate process has to be run to avoid exceeding the critical anode potential (<em>E</em><sub>cr</sub>) in order to keep the potential losses low and to achieve a long lifetime of the DSAs. At <em>E</em><sub>cr</sub> anodic polarisation curves in chlorate electrolyte bend to higher Tafel slopes, causing increasing potential losses and accelerated ageing of the anode. Therefore the impact on the anode potential and on <em>E</em><sub>cr</sub> of different electrolyte parameters and electrolyte impurities was investigated. Additionally, the work aimed to investigate the impact of an addition of chromate on oxygen evolution and concentration profiles under conditions reminiscent of those in the chlorate process (high ionic strength, 70 °C, ruthenium based DSA, neutral pH), but without chloride in order to avoid hypochlorite formation. For this purpose a model, taking into account mass transport as well as potential- and concentration-dependent electrode reactions and homogeneous reactions was developed. Water oxidation is one of the side reactions considered to decrease the current efficiency in chlorate production. The results from the study increase the understanding of how a buffer/weak base affects a pH dependent electrode reaction in a pH neutral electrolyte in general. This could also throw light on the link between electrode reactions and homogeneous reactions in the chlorate process.</p><p>It was found that the mechanism for chloride oxidation is likely to be the same for potentials below <em>E</em><sub>cr</sub> as well as for potentials above <em>E</em><sub>cr</sub>. This was based on the fact that the apparent reaction order as well as α<sub>a</sub> seem to be of the same values even if the anode potential exceeds<em> E</em><sub>cr</sub>. The reason for the higher slope of the polarisation curve above <em>E</em><sub>cr</sub> could then be a potential dependent deactivation of the active sites. Deactivation of active ruthenium sites could occur if ruthenium in a higher oxidation state were inactive for chloride oxidation.</p><p>Concentration gradients of H<sup>+</sup>, OH<sup>-,</sup> CrO<sub>4</sub> <sup>2-</sup> and HCrO<sub>4</sub> <sup>- </sup>during oxygen evolution on a rotating disk electrode (RDE) were predicted by simulations. The pH dependent currents at varying potentials calculated by the model were verified in experiments. It was found that an important part of the chromate buffering effect at high current densities occurs in a thin (in the order of nanometers) reaction layer at the anode. From comparisons between the model and experiments a reaction for the chromate buffering has been proposed. Under conditions with bulk pH and chromate concentration similar to those in the chlorate process, the simulations show that the current density for oxygen evolution from OH<sup>-</sup> would be approximately 0.1 kA m<sup>-2</sup>, which corresponds to about 3% of the total current in chlorate production.</p>
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Organoclay Preparation For Anionic Contaminant Removal From WaterInam, Deniz 01 September 2005 (has links) (PDF)
Increasing concern about the pollution of environment by inorganic and organic chemicals arising from naturally occurring ecological events and industrial processes has created a need for the search of new techniques in the removal of these contaminants.
One of the natural material that can be used in such processes is clay. Clay minerals have large surface areas and high cation exchange capacities which enables them to be modified by cationic surfactants. The material prepared, often called as & / #8216 / organoclay& / #8217 / , can be used to remove hydrophobic organic and anionic contaminants from polluted water.
Among the anionic contaminants, oxyanions such as nitrate, chromate are detrimental to human life and environment even at µ / g/L- mg/L levels. Application of organoclays for their removal from polluted water appears as one of the practical and rather cheap solution.
In this study, a local clay from Ankara-Kalecik (Hanç / ili Bentonite) was modified by hexadecyltrimethylammonium bromide (HDTMA-Br) to a level of twice of its cation exchange capacity. This process alters the negatively charged surface of the clay into a positively charged one, providing sites for the removal of anionic contaminants. In this study, the degree of HDTMA+ uptake by the clay within a period of eight hours is found to be 97% of the initial amount added.
In desorption studies it was revealed that only about 1% of the sorbed HTDMA+ was leached in a seven days of water-organoclay interaction revealing a rather stable organoclay structure in aqeous media.
Sorption experiments with nitrate, borate, and chromate solutions were performed in order to determine the anion sorption capacity of the organoclays prepared. It turns out that while untreated clay has insignificant capacity, the modified clay can remove considerable amount of nitrate and chromate ions from aqeous solutions. While the nitrate sorption was increased about eleven fold, change in chromate sorption was reached to a level of twenty fold compared to that of the untreated clay. Sorption data for nitrate and chromate are both well described by the Langmuir isotherms. No significant change was observed in case of borate-organoclay interaction. Desorption of nitrate and chromate ions from organoclay surface were also investigated. Sorption of these oxyanions were found to be almost irreversible in aqeous media.
The results imply that a properly prepared organoclay can be used for the removal of oxyanions, such as nitrate and chromate from polluted water systems.
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Behandlungskonzept für schwermetallkontaminierte Wässer durch Reduktion und Metallhydroxidfällung : Verfahren zur Reinigung Cr(VI)-haltiger Modellabwässer mit Zink- und Eisenpartikeln /Schmidbauer, Erwin. January 2003 (has links)
Universiẗat, Diss.--Karlsruhe, 2003.
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Alternative oxidants and processing procedures for pyrotechnic time delaysRicco, Isabel Maria Moreira 13 September 2005 (has links)
This study was directed at the pyrotechnic time delay compositions that are used in detonator assemblies. The objectives were to: --Investigate effective alternatives for the barium and lead-based oxidants currently used, maintaining the use of silicon as fuel --Develop easy to use, realistic measurement techniques for burn rates and shock tube ignitability --Determine the variables that affect burn rate, and --Evaluate alternative processing routes to facilitate intimate mixing of the component powders. Lead chromate and copper antimonite were found to be suitable oxidants for silicon in time delay compositions. They were ignitable by shock tubing, a relatively weak ignition source. The measured burn speeds for these systems showed a bimodal dependence on stoichiometry. Measured burn rates varied between 6-28 mm/s. Lead chromate is potentially a suitable alternative to the oxidant currently used in the medium burn rate commercial composition. It burns faster than copper antimonite. The latter is potentially a suitable replacement oxidant for the slow and medium compositions. Antimony trioxide-based compositions exhibited unreliable performance with respect to ignition with shock tubing. The addition of aluminium powder or fumed silica was found to reduce the burn rate. Increasing the silicon particle size (<3,5<font face="symbol">m</font>m) also decreased the burn speed for copper antimonite and lead chromate compositions. Addition of fumed silica improved the flow properties of the lead chromate, copper antimonite and antimony trioxide powders allowing for easier mixing. The silicon powder was found to react violently with water in alkaline solutions. This makes particle dispersion in a wet-mixing process problematic. / Dissertation (MEng (Chemical Engineering))--University of Pretoria, 2006. / Chemical Engineering / unrestricted
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Remobilization of trivalent chromium and the regeneration of in situ permeable reactive barriers during operationKaimbi, L.A. (Lapaka Albertina) January 2014 (has links)
Chromium exists largely in two oxidation states, namely hexavalent chromium (Cr(VI))
which is carcinogenic, mutagenic to living organisms including humans and trivalent
chromium (Cr(III)) which is known to be 1000 times less toxic than Cr(VI). It is therefore
desirable in most cases to reduce Cr(VI) to Cr(III). Various studies have been conducted on
the Cr(VI) reduction process either in situ or ex situ. However in situ bioremediation using
permeable reactive barrier system appears as a potential and attractive technology compared
to other in situ technologies. This study was conducted to evaluate the reduction of Cr(VI) to
Cr(III) in the short term and regeneration of the biological reactive barrier to achieve
continuous long term operation. It was observed from the study that the chromium hydroxide
Cr(OH)3(s) precipitated and thus affected the porosity and hydraulic conductivity of the
barrier system. It was therefore proposed to implement a regeneration process involving
remobilization of precipitated Cr(OH)3 using a dilute acid (0.1% HCl) and recover Cr(III) by
electrokinetics.
Lowering the pH in the reactor introduced harsh conditions which necessitated the evaluation
of a possible culture shift during the regeneration phase. Microbial culture composition
during bioremediation and after soil washing was evaluated using a 16S rRNA finger printing
method. The microbial barrier was initially inoculated with indigenous bacterial species from
dried sludge. The results presented in the phylogenic tree diagrams confirm that, after
microbial barrier system operation, the well-known Cr(VI) reducers Bacillus mycoides, Lysinibacillus fusiformis and Micrococcus lylae were the predominant species in the
microbial community of the barrier.
The microbial barrier system successfully achieved near complete removal of Cr(VI),
whereby approximately 75% Cr(VI) removal was achieved within 63 days of operation. The
formation of Cr(OH)3(s) was observed in the second week of operation. After 4 weeks of
operating the mesocosm under soil washing with 0.1% HCl and electrokinetics remediation
with a DC voltage of 50-150 V an increase in total chromium (73%) was observed suggesting
that the trapped chromium species in the mesocosm was effectively remobilized with the
assumption that Cr(III) had attached to the cathode forming a white-yellow precipitate layer
around the cathode. Additionally more than 95% Cr(VI) was transformed to lower toxicity
Cr(III) during electrokinetics and soil washing remediation. However, one of the limitations
of electrokinetics is near anode focusing effect whereby a layer of precipitate is formed
around the anode that lead to the reduction of efficiency of the technology. / Dissertation (MSc)--University of Pretoria, 2014. / lk2014 / Chemical Engineering / MSc / Unrestricted
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Critical potential and oxygen evolution of the chlorate anodeNylén, Linda January 2006 (has links)
In the chlorate process, natural convection arises thanks to the hydrogen evolving cathode. This increases the mass transport of the different species in the chlorate electrolyte. There is a strong connection between mass transport and the kinetics of the electrode reactions. A better knowledge about these phenomena and their interactions is desirable in order to understand e.g. the reasons for deactivation of anode coatings and what process conditions give the longest lifetime and the highest efficiency. One of the aims of his work was to understand how the chlorate process has to be run to avoid exceeding the critical anode potential (Ecr) in order to keep the potential losses low and to achieve a long lifetime of the DSAs. At Ecr anodic polarisation curves in chlorate electrolyte bend to higher Tafel slopes, causing increasing potential losses and accelerated ageing of the anode. Therefore the impact on the anode potential and on Ecr of different electrolyte parameters and electrolyte impurities was investigated. Additionally, the work aimed to investigate the impact of an addition of chromate on oxygen evolution and concentration profiles under conditions reminiscent of those in the chlorate process (high ionic strength, 70 °C, ruthenium based DSA, neutral pH), but without chloride in order to avoid hypochlorite formation. For this purpose a model, taking into account mass transport as well as potential- and concentration-dependent electrode reactions and homogeneous reactions was developed. Water oxidation is one of the side reactions considered to decrease the current efficiency in chlorate production. The results from the study increase the understanding of how a buffer/weak base affects a pH dependent electrode reaction in a pH neutral electrolyte in general. This could also throw light on the link between electrode reactions and homogeneous reactions in the chlorate process. It was found that the mechanism for chloride oxidation is likely to be the same for potentials below Ecr as well as for potentials above Ecr. This was based on the fact that the apparent reaction order as well as αa seem to be of the same values even if the anode potential exceeds Ecr. The reason for the higher slope of the polarisation curve above Ecr could then be a potential dependent deactivation of the active sites. Deactivation of active ruthenium sites could occur if ruthenium in a higher oxidation state were inactive for chloride oxidation. Concentration gradients of H+, OH-, CrO4 2- and HCrO4 - during oxygen evolution on a rotating disk electrode (RDE) were predicted by simulations. The pH dependent currents at varying potentials calculated by the model were verified in experiments. It was found that an important part of the chromate buffering effect at high current densities occurs in a thin (in the order of nanometers) reaction layer at the anode. From comparisons between the model and experiments a reaction for the chromate buffering has been proposed. Under conditions with bulk pH and chromate concentration similar to those in the chlorate process, the simulations show that the current density for oxygen evolution from OH- would be approximately 0.1 kA m-2, which corresponds to about 3% of the total current in chlorate production. / QC 20101122
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Zinc Sulfide: manganese doped Quantum rods for detection of metal ions and a business model for future salesTeblum, Andrew 01 January 2014 (has links)
Hexavalent chromium is an extremely carcinogenic chemical that has been widely produced in the United States. This has led to major waste contamination and pollution throughout the country. According to the Environmental Working Group Hexavalent chromium has been found in 89% of city tap water. Most people believe they are safe using regular home filter systems however that is not true. A more expensive ion exchange water treatment unit is required. Therefore to protect yourselves from this carcinogenic metal a reliable test is required. In this study we have developed a Zinc Sulfide Manganese doped Quantum Rod technology to detect for presence of chromate and other harmful transitional metals in drinking water. Quantum Rods were synthesized using a hydrothermal reaction method. They were fully characterized using UV-visible absorption spectroscopy, fluorescence emission spectroscopy, X-ray Photoelectric Spectroscopy (XPS) and High Resolution Transmission Electron Microscopy (HRTEM). Quantum Rod metal detection studies were done with 28 different ions in a 96-well fluorescent plate reader. Results show that highest sensitivity to 8 ions including the toxic ions of chromate and mercury allowing us to create a sensor to detect these items.
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Chromium (VI) Reduction by <i>Shewanella oneidensis</i> MR-1 in Elevated Chromium Concentrations Exhibited in Corrosion Resistant Coatings.Miller, Robert B., II 05 June 2014 (has links)
No description available.
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