New materials for intermediate-temperature solid oxide fuel cells to be powered by carbon- and sulfur-containing fuels

Yang, Lei

04 April 2011

Unlike polymer electrolyte fuel cells, solid-oxide fuel cells (SOFCs) have the potential to use a wide variety of fuels, including hydrocarbons and gasified coal or different types of ample carbonaceous solids. However, the conventional anode for an SOFC, a composite consisting of nickel and yttria-stabilized-zirconia (YSZ), is highly susceptible to carbon buildup (coking) and deactivation (poisoning) by contaminants commonly encountered in readily available fuels. Further, the low ionic conductivity of the electrolyte and the poor performance of the cathode at lower temperatures require SOFCs to operate at high temperatures (>800°C), thereby increasing costs and reduce system operation life. Thus, in order to make SOFCs fully fuel-flexible, cost-effective power systems, the issues of anode tolerance to coking and sulfur poisoning as well as the slow ionic conduction in the electrolyte and the sluggish kinetics at the cathode need to be addressed. In this thesis, a novel electrolyte was shown to have the highest ionic conductivity below 750°C of all known electrolyte materials for SOFCs applications, which allowed for fabrication of a thin-electrolyte cell with high power output at lower temperatures. The detailed electrochemical analyses of BZCYYb conductor revealed that the conductivities were sensitive to doping and partial pressure of oxygen, hydrogen, and water. When used in combination with Ni as a composite anode (Ni-BZCYYb), it was shown to provide excellent tolerance to coking and sulfur poisoning. Extensive investigations on surfaces of BZCYYb and Ni by Raman Spectroscopy and Scanning Auger Nanoprobe disclosed that its unique ability appears linked to the mixed conductor's enhanced catalytic activity for sulfur oxidation and hydrocarbon cracking/reforming, as well as enhanced multilayer water adsorption capability. In addition, the nanostructured oxide layers on Ni from dispersion of BZCYYb traces during high-temperature calcinations may effectively suppress the formation of carbon from dehydrogenation. Based on the fundamental understanding on surface properties, a new and simple modification strategy was developed to hinder the carbon-induced deactivation of the state-of-the-art Ni-YSZ anode. Compared to the complex Ni-BZCYYb anode, this modified Ni-YSZ anode could be readily adopted in the latest fuel cell systems based on YSZ electrolyte. The much-improved power output and tolerance to coking of the modified Ni-YSZ anode were attributed to the nanostructured BaO/Ni interfaces observed by synchrotron-based X-ray and advanced electron microscopy, which readily adsorbed water and facilitated water-mediated carbon removal reactions. Density functional theory (DFT) calculations predicted that the dissociated OH from H₂O on BaO reacted with C on Ni near the BaO/Ni interface to produce CO and H species, which were then electrochemically oxidized at the triple-phase boundaries of the anode. Also, some new insights into the sulfur poisoning behavior of the Ni-YSZ anode have been revealed. The so-called "second-stage poisoning" commonly reported in the literatures can be avoided by using a new sealant, indicating that this poisoning is unlikely the inherent electrochemical behavior of a Ni-YSZ anode but associated with other complications. Furthermore, a new composite cathode with simultaneous transport of proton, oxygen vacancies and electronic defects was developed for low-temperature SOFCs based on oxide proton conductors. Compared to the conventional oxygen ion-electron conducting cathode, this cathode is very active for oxygen reduction, extending the electrochemically active sites and significantly reducing the cathodic polarization resistance. Towards the end, these findings have great potential to dramatically improve the economical competitiveness and commercial viability of SOFCs that are driven by cost-effective and renewable fuels.

Oxygen reduction

Solid oxide fuel cells

Electrical conductivity

Coking

Sulfur poisoning

Sulfur

Anodes

Renewable energy sources

Materials science

On the mechanisms of sulfur isotope fractionation during microbial sulfate reduction

Leavitt, William Davie

04 June 2015

Underlying all applications of sulfur isotope analyses is our understanding of isotope systematics. This dissertation tests some fundamental assumptions and assertions, drawn from equilibrium theory and a diverse body of empirical work on biochemical kinetics, as applied to the multiple sulfur isotope systematics of microbial sulfate reduction. I take a reductionist approach, both in the questions addressed and experimental approaches employed. This allows for a mechanistic, physically consistent interpretation of geological and biological sulfur isotope records. The goal of my work here is to allow interpreters a more biologically, chemically and physically parsimonious framework to decipher the signals coded in modern and ancient sulfur isotope records. / Earth and Planetary Sciences

Geochemistry

Geobiology

Microbiology

enzyme isotope fractionation

geomicrobial kinetic isotope effects

microbial sulfate reduction

multiple sulfur isotopes

Phanerozoic oxygen

sulfur cycle

IMPROVING THE CONVERSION OF THE SULFUR DIOXIDE - LIME REACTION BY USING ADDITIVES

Dombek, Priscilla Emily, 1961-

January 1986

No description available.

Air quality management.

Functional Characterization and Surface Mapping of Frataxin (FXN) Interactions with the Fe-S Cluster Assembly Complex

Thorstad, Melissa

16 December 2013

In 1996, scientists discovered a connection between the gene for the human protein frataxin (FXN) and the neurodegenerative disease Friedreich’s ataxia (FRDA). Decreased FXN levels result in a variety of aberrant phenotypes including loss of activity for iron-sulfur containing enzymes, mitochondrial iron accumulation, and susceptibility to oxidative stress. These symptoms are the primary focus of current therapeutic efforts. In contrast our group is pursuing an alternate strategy of first defining FXN function at a molecular level then using this information to identify small molecule functional replacements. Recently, our group has discovered that FXN functions as an allosteric activator for the human Fe-S cluster assembly complex. The work presented here helps to further define molecular details of FXN activation and explain how FRDA missense mutants are functionally compromised. First, the FRDA missense mutants L182H and L182F were investigated. Unlike other characterized FRDA missense mutants, the L182F variant was not compromised in its ability to bind and activate the Fe-S assembly complex. The L182H variant exhibited an altered circular dichroism signature; suggesting a change in secondary structure relative to native FXN, and rapidly degraded. Together these studies suggest that L182 variants are less stable than native FXN and are likely prone to degradation in FRDA patients. Second, as a regulatory role of FXN suggests that its function is likely controlled by environmental stimuli, different maturation forms of FXN as well as post-translational modification mimics were tested as mechanisms to control FXN regulation. Here experiments were designed to test if a larger polypeptide form of FXN represents a functional form of the protein. Kinetic and analytical ultracentrifugation studies revealed a complex heterogeneous mixture of species some of which can activate the Fe-S assembly complex. A previously identified acetylation site was also tested using mutants that mimic acetylation. These mutants had little effect on the ability of FXN to bind and activate the assembly complex. Third, mutagenesis experiments were designed in which the FXN surface residues were replaced with alanine and the resulting variants were tested in binding and activity assays. These experiments revealed a localized “hot-spot” on the surface of FXN that suggests small cyclic peptide mimics might be able to replace FXN and function as FRDA therapeutics. Unexpectedly, one of the FXN variants exhibited significantly tighter binding and could have relevance for therapeutic development.

Frataxin

Friedreich's ataxia

FRDA

alanine scanning

lysine acetylation

allosteric regulation

oligomerization

Adsorptive Removal of Refractory Sulphur and Nitrogen Compounds from Transportation Fuels

Iravani, Amir

06 November 2014

The reduction of sulphur in transportation fuel has gained significant importance as the regulatory agencies worldwide react to air quality concerns and the impact of sulphur oxides on the environment. The overall objective of this research was to identify, develop and characterize, based on underlying scientific principles, sorbents that are effective in removal of refractory sulphur compounds from fuel through the process of selective adsorption. It was determined that impregnation of powdered activated carbon with a transition metal (TM) significantly boosted the adsorption performance of the activated carbon. It is hypothesized that the impregnation resulted in the formation of new adsorptive sites that strongly interacted with the lone pairs of electrons on sulphur and nitrogen while having minor impact on the existing oxygen functional groups on the surface of the activated carbon. The percent loading of the TM was determined through wet adsorption study. The best performing sorbent was shown to have maximum adsorption capacities of approximately 1.77 and 0.76 mmol-S/g-sorbent for DBT and 4,6 DMDBT, respectively, with approximately 100% regenerability through solvent wash and thermal treatment. On average, the PTM impregnation showed approximately 137% increase in adsorption capacity of the activated carbon. The sorbent also has good adsorption capacities for organo-nitrogen compounds (i.e., quinoline and carbazole) and a low selectivity towards aromatics, which is desired in adsorptive desulphurization. The surface morphology of the activated carbon, the oxygen functional groups on the surface of the activated carbon, as well as strong (chemisorption) interaction between the TM???s partly vacant and far reaching ???d??? orbital and lone pair electrons on sulphur and nitrogen are considered to be the main contributing factors to the observed enhancement. It was established in this study that the adsorption isotherms of the impregnated activated carbons best fit Sips isotherm equation, which is a combination of the Langmuir and Freundlich equations. This finding fits well with our initial hypothesis regarding the introduction of new adsorptive sites as a result of TM impregnation and that the sites did not fit well with Langmuir???s monolayer and uniform adsorption mechanism. A kinetic study of the sulphur adsorption using a flow reactor showed a good fit with pseudo second order kinetic model, indicative of an adsorption that is highly dependent on the concentration of available sites on the surface of the sorbent. On average, as expected, the TM impregnated ACC exhibited a higher initial rate of adsorption. The adsorption onto TM sites tends to be more exothermic than adsorption (mainly physisorption) on activated carbon. Therefore, more thermodynamically favoured chemisorption is expected to occur more rapidly than physisorption. It was determined that on average, the initial adsorption rate does not change significantly with temperature while the sulphur adsorption capacity decreases with increase in temperature. It is postulated that the increase in temperature increases surface diffusivity but impedes diffusion flux. The impediment of the diffusion flux will result in reduction in adsorbed quantity. It was also shown that the intra-particle diffusion exists in the adsorption of DBT on TM impregnated activated carbon, however, it is not likely that the overall adsorption is controlled or noticeable impacted by it. As the temperature of the reactor increases the Weber-Morris intra-particle diffusion plot moves away from the origin, and thus intra-particle diffusion becomes less of a controlling mechanism. This further confirms the fact that the boundary layer (i.e., surface diffusion) and potentially adsorptive interactions at the surface are the dominating mechanisms in the sulphur adsorption onto TM impregnated activated carbon. It was determined that the distribution of TM species on the surface of the activated carbon is relatively inhomogeneous, with some areas showing well dispersed TM species while other areas showing large clusters. Different impregnation method that can improve dispersion on the surface may significantly enhance adsorption performance of the sorbent. Furthermore, in this study impregnation of activated carbon using several other transition metals were examined. It was determined that other less expensive transition metals can also improve the adsorption performance of the activated carbon. Further study on less expensive options for impregnating the activated carbon may be beneficial.

Síntese e estudos de Diels-Alder de 2-sulfinil-3,6-dimetil-1,4-benzoquinonas visando a síntese de precursores enantiopuros do hirsuteno / Synthesis and studies Diels-Alder 2-sulfinyl-3,6-dimethyl-1, 4-benzoquinone aiming at the synthesis of enantiopure precursors hirsuteno

Andrea Luzia Ferreira de Souza

21 May 2004

Foram preparadas algumas 2-sulfinil-3,6-dimetil-1,4-benzoquinonas racêmicas (contendo substituintes p-tolila, terc-butila, iso-butila e iso-propila ligados ao enxofre) e estudadas as suas reações de Diels-Alder com ciclopentadieno, sob condições térmicas e catalíticas. Com estes estudos foi constatada a habilidade destas quinonas em gerar majoritariamente certos tipos de adutos, dependendo das condições utilizadas. Na ausência de catalisadores, formaram-se principalmente os adutos resultantes da aproximação do ciclopentadieno sobre a dupla C-C não sulfinilada, pela face da quinona para a qual não está voltado o par de elétrons do enxofre, quando a ligação C-S se encontra na conformação s-cis. O uso de BF3.Et2O provocou uma inversão da face atacada, mas manteve a quimiosseletividade observada na ausência deste catalisador. Já, pelo emprego de ZnBr2, houve preferência do ataque do ciclopentadieno sobre a dupla C-C da quinona sulfinilada. As conclusões de tal estudo permitiram selecionar as condições a serem utilizadas para a obtenção de certos adutos com vistas a serem estes depois empregados para a síntese de um precursor enantiopuro do hirsuteno. Os trabalhos prosseguiram com ensaios para se determinar a melhor forma de obtenção de tal precursor: i) fotoisomerização a compostos gaiola seguida de dessulfurização ou ii) remoção do enxofre do aduto de Diels-Alder e fotociclização do produto dessulfurizado. A reação de fotociclização do aduto de Diels-Alder formado pela reação do dieno sobre a dupla sulfinilada da quinona gerou o compostogaiola dessulfurizado e também um novo aduto, cuja estrutura supõe-se ser a de uma enodiona hidroxilada, mas de configuração trans entre os anéis. Pela rota dessulfurizante ii), o mesmo composto foi obtido quando se empregou o hidreto de tributilestanho/AIBN, também ao lado do compostogaiola. As melhores condições para a obtenção de um precursor do hirsuteno enantiopuro foram estabelecidas como sendo aquelas que seguem a rota ii), isto é, dessulfurização do aduto de Diels-Alder resultante do ataque do ciclopentadieno sobre a dupla não sulfinilada, em condições catalíticas (BF3Et2O), quando o grupo sulfinila ligado à quinona está com a configuração S e contém um substituinte isso-propila, seguida de fotociclização do aduto sem enxofre. / Some racemic 2-tolyl- or 2-alkylsulfinyl-3,6-dimethyl-1,4-benzoquinones (alkyl is terc-butyl or iso-butyl or iso-propyl) were prepared and submitted to the Diels-Alder reactions with cyclopentadiene, under thermal or catalytic conditions. It was verified that the sulfinyl group is able to control the chemo- and diasterofaciaselectivity, giving rise to different adducts, depending on the reactions conditions. In the absence of catalyst, the above mentioned quinones underwent cycloaddition mainly on the non-sulfinylated quinoidic C-C double bond. The resulting adducts arised from the approach of diene from the more hindered face of the quinone, ie that one where the lone pair at sulfur is not located on, when the C-S bond is in a s-cis conformation. The use of BF3.Et2O diverted the cycloaddition to the other face, but kept the same chemoselectivity. When ZnBr2 was employed, the chemoselectivity was reversed, being the sulfinylated C-C double bond preferentially attacked by cyclopentadiene. The conclusions which arised from this study allowed the selection of the best set of conditions for obtaining the structurally more adequate sulfinyl-Diels-Alder adducts for the synthesis of enantiomerically pure hirsutene. Two pathways were assayed in order to transform the sulfinylated Diels-Alder adducts into a structurally closely related precursor of hirsutene: i) photoisomerization of the above mentioned Diels-Alder adducts followed by desulfurization of the resulting cage-compounds or ii) removal of the sulfurated moiety from the sulfinyl-Diels-Alder adducts followed by photocyclization. Irradiation of the Diels-Alder adduct containing a sulfinyl group at the ring junction led to the desired sulfur-free cage-compound in amixture with other product. The proposed structure for this new compound is based on a Diels-Alder adduct with a trans configuration, with an hydroxyl group linked to the enedionic system. This same compound was obtained, in amixture with the sulfur-free Diels-Alder adduct, when route ii) was tested using tributyltin hydride/AIBN as desulfurizating agent. In summary, the best conditions for the synthesis of an enantiomerically pure precursor of hirsutene is desulfurization of the Diels-Alder adduct resulting from the BF3.Et2O catalysed cycloaddition between the cyclopentadiene and 2-(SS)-iso-propylsulfinyl-3,6-dimethyl-1,4-benzoquinone, followed by photoisomerization of the sulfur-free product.

Catalisador

Compostos de enxofre

Enxofre

Reações Orgânicas

Síntese Orgânica

Sulfona

Sulfóxido

Catalyst

Organic Reactions

Organic synthesis

Sulfone

Sulfoxide

Sulfur

Sulfur compounds

SULFUR-TOLERANT CATALYST FOR THE SOLID OXIDE FUEL CELL

Bozeman, Joe Frank, III

30 June 2010

No description available.

Chemical Engineering

Chemistry

Energy

Engineering

Environmental Engineering

Materials Science

SOFC

fuel cell

sulfur resistant

sulfur tolerance

catalyst

gaussian

PERFORMANCE ANALYSIS OF A SUCCESSIVE ALKALINITY PRODUCING SYSTEM TREATING ACID MINE DRAINAGE AT SIMMONS RUN IN COSHOCTON COUNTY, OHIO

Krohn, Jeremy P.

20 April 2007

No description available.

Acid mine drainage

Passive treatment

sulfur reducing bacteria

sulfur reduction

alkalinity production

constructed wetland

metals

sludge

mass balance

Application of synthetic molecular sieve zeolites and silica gel towards the separation of sulfur dioxide from combustion gases

Wright, George Todd

January 1979

An evaluation of several commercial adsorbents for use as contacting media in a process for combustion gas desulfurization was performed. Linde Synthetic Molecular Sieves types 13X and AW500 and Davison Silica Gel were the materials studied. The motivation for this investigation was based on the premise that a suitable method for removing sulfur dioxide from combustion gas streams has not been realized. Sulfur dioxide adsorption capacities were obtained for equilibrium (non-flow) and dynamic flow conditions. Sulfur dioxide adsorption on the molecular sieves could be described by a modified Langmuir expression of the form q/q_m = kc^1/n/ 1 + kc^1/n Calculated isosteric heats of adsorption were found to agree with measured data. Small scale dynamic studies consisted of contacting the adsorbents in a packed column with a simulated combustion gas. Evaluation of the adsorbent materials consisted of monitoring the effluent gas concentration after exposure to a step change in sulfur dioxide concentration. Sulfur dioxide loadings were greatest for the type 13X molecular sieve followed by AW500 molecular sieve. The effect of gas throughput was minimal which suggests that mass transfer was adsorbent side controlling. As gas temperature increased, sulfur dioxide adsorption decreased linearly for 100 percent sulfur dioxide concentration and non-linearly for low concentrations (0.003 percent). The effect of water vapor on sulfur dioxide adsorption capacity was determined by monitoring the effluent gas composition for specified sulfur dioxide-water vapor mixtures. Breakthrough time for sulfur dioxide was found to be an inverse function of the inlet water vapor concentration. For a typical combustion gas stream, (8 percent water vapor) the breakthrough time is roughly 10 percent of the water vapor free value. Based on the results obtained, a shallow bed (0.15m, 0.5 ft) of either type 13X or AW500 molecular sieve removed 5 to 3 times that of activated charcoal for a gas temperature of 57.2°C (135°F) and low gas pressure drop 4.6 cm H₂0 (1.85 in. H₂0). Adsorption degradation studies were performed to determine the loss in sulfur dioxide adsorption capacity after adsorbent regeneration. Both the 13X and AW500 molecular sieve could be regenerated, but the loss in adsorption capacity depended on the gas contacting conditions. X-ray spectroscopy was used to determine the homogeneity of the sulfur distribution within the adsorbents. The sulfur dioxide adsorption capacity for subsequent regeneration cycles was found to be a function of the Al₂O₃/SiO₂ ratio of the molecular sieve. Application of the molecular sieve adsorbents in a simulated combustion gas for sulfur dioxide removal was found to be superior to several adsorbents for the temperature range 21-76°C (70-170°F). However, as gas temperature increases, sulfur dioxide adsorption decreases. No adsorption of sulfur dioxide above 148°C (300°F) could be measured. / Ph. D.

LD5655.V856 1979.W74

Combustion gases

Gases -- Separation

Molecular sieves

Zeolites

Coal -- Sulfur content

Sulfur dioxide

Separation (Technology)

The Physiological and Developmental Effects of Sulfur Nutrition and Light Intensity on Sulfur Deficiency Symptoms in <i>Phaseolus Vulgaris</i>

Harney, Dennis James

17 April 2003

No description available.

Biology, Plant Physiology

bean

Phaseolus vulgaris

developmental index

developmental age

plant age

plastochron index

plastochron index derived days

sulfur

sulfur nutrition

sulfur deficiency

light

light level

light sensitivity

photosensitivity