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21	Trade-offs And Social Behaviour In The Cellular Slime Moulds Sathe, Santosh 10 1900 (has links) (PDF) By combining laboratory experiments with field work, I have looked at the following aspects of cellular slime mould (CSM) biology: (a) the genetic structure of social groups (fruiting bodies) in the wild and its relation to the role of large mammals as dispersal agents; (b) social behaviour in clonal, intra-species polyclonal and interspecies social groups and (c) fitness-related trade-offs with respect to life history traits as a possible mechanism for coexistence and cooperative behaviour in CSMs. The major findings of this study are as follows: (a) individuals belonging to different strains of a species, different species and genera occur in close proximity, even on a speck of soil (250µm–1mm) or the same dung pat; (b) social groups formed in the wild by Dictyostelium giganteum and D. purpureum are generally multiclonal; (c) genetically diverse strains can co-aggregate and form chimaeric social groups; (d) in chimaeric social groups, strains differ in their relative sporulation efficiencies; (e) the fact that strains co-exist in spite of this may be attributable in part to trade-offs between various fitness-related traits as can be demonstrated in the case of wild isolates of D. giganteum in pair wise mixes. The Dictyostelids or CSMs are haploid, eukaryotic, soil dwelling social amoebae with an unusual life cycle (Bonner, 1967; Raper, 1984). They exist as single cells in the presence of food (bacteria, yeast, fungal spores). Once the food is exhausted, they enter the social phase of their life cycle. Approximately 102 to 106 amoebae aggregate at a common collection point and form a starvation resistant structure called the fruiting body. In many species a fruiting body is made up of an aerial stalk of dead cells and a ball of viable spores on top. In other CSM species (not part of this study), all amoebae in a fruiting body differentiate into spores and the stalk is an extracellular secretion. The CSM life cycle raises fundamental questions related to the evolution of an extreme form of ‘altruism’ in the form of reproductive division of labour in social groups. The spore–stalk distinction in the CSMs is analogous to the germ–soma distinction in metazoans, although, the CSMs achieve multicellularity not by repeated divisions of a zygote but via the aggregation of many cells which may or may not be clonally related (Bonner, 1982; Kaushik and Nanjundiah, 2003). Social behaviour in the CSMs offers interesting parallels to what is seen in the social insects (Gadagkar and Bonner, 1994). The origin and maintenance of ‘altruism’ has been a long-standing issue in sociobiology. Because of their simple life cycle and experimental tractability, the CSMs are ideal for studying the evolutionary origin and maintenance of social behaviour, in particular of ‘altruistic’ behaviour. By elevating spores above soil level, stalk cells, protect them from noxious compounds and predators present in soil and also facilitate their passive dispersal. In the course of doing so they die. The death of stalk cells appears to be an extreme form of altruism. Knowledge of the genetic structure of social groups and populations including patterns of kinship is essential for modelling the evolution of ‘altruism’. Thus, it is important to understand the genetic structure of CSM social groups in the wild. For this, social groups (fruiting bodies) of CSMs were isolated from undisturbed forest soil of the Mudumalai forest reserve in South India. Soil and animal dung samples were brought to the laboratory and quasi-natural social groups were generated by inoculating the samples on non-nutrient agar. The fruiting bodies from various CSM species were formed by these isolates. Since soil and dung samples were not perturbed in any way, the fruiting bodies were formed as they would have in nature. When compared to soil, dung samples contained a higher CSM diversity and more CSM propagules. The presence of CSMs in fresh animal dung makes it likely that they were transported and dispersed over long distances through the gut of these animals. Such dispersal is likely to be preceded by a thorough mixing of spores in the gut. That increases the probability of co-occurrence of different genotypes in a social group. This possibility was confirmed by genetically characterizing spores in social groups of Dictyostelium giganteum and D. purpureum collected from the wild. Random amplification of polymorphic DNA (RAPD), a simple and reliable molecular technique, was used for genotyping spores within a fruiting body. 17 fruiting bodies (8 from animal dung and 9 from soil) were studied. 15 out of 17 (9 out of 11 of D. giganteum and 6 out of 6 D. purpureum) were polyclonal; the minimum number of distinct clones in a single fruiting body was 3 to 7 (animal dung) and 1 to 9 (soil). Therefore in D.giganteum and D. purpureum, chimaeric social groups seem to be the norm. This suggests that other species of CSMs form intra-species chimaeric social groups in wild, though clonal fruiting bodies occur too. The next objective of this thesis was to test whether genetic heterogeneity had functional consequences. That is, when different strains come together in an aggregate, do they contribute equally to the reproductive (spore) and non-reproductive (stalk) pathways? Amoebae of different clones (strains) of D. giganteum or D. purpureum were mixed and developed together and the number of spores formed by each strain was counted. These experiments confirmed that strains of D. giganteum or D. purpureum can aggregate together and form chimaeric fruiting bodies. The ability to mix (measured as the frequency of chimaerism) depended on the strains used and varied from one mix to another. One strain was often found to ‘exploit’ the other during sporulation, that is, it formed more spores than its expected share. Despite this, strains are found in very close proximity in the soil, which raises an important question: when one strain is more efficient at sporulating than other, how can the two co-exist stably? To investigate what might lie behind the stable co-existence of strains, I studied various fitness-related traits in the life cycle of D. giganteum. They included the rate of cell division, the time taken to go through multicellular development, the efficiency of slug migration through various depths of soil and the probability of differentiation into a spore. Measurements were carried out on strains taken separately and on their pair wise mixes. Five different D. giganteum wild strains (46a3, 46d2, 48.1a1, F5 and F16) were used. All were isolated from the Mudumalai forest (India). 46a3 and 46d2 came from soil within 10 cm of each other, 48.1a1 from soil about 200m away from 46a3; and F5 and F16 from the same fruiting body (Kaushik et al., 2006; Sathe et al., 2010). Members of a pair differed significantly in the measured fitness-related traits. For example, in the case of 48.1a1 and 46d2, 48.a1 grew faster than 46d2 both individually and in a mix. After starvation, 48.1a1 formed fruiting bodies faster than 46d2; a mix of the two developed at the rate of the faster member, implying that the slower one (46d2) gained from the association with 48.1a1. During slug migration, slugs formed by 48.1a1 came up through a higher depth of soil than 46d2 slugs and did so earlier. Chimaeric slugs were like the more efficient member, 48.1a1, in terms of the maximum depth of soil that was covered, but like the less efficient member, 46d2, in terms of the time taken for slugs to be seen on the soil surface. 48.1a1 seems to have an advantage over 46d2 in all these respects. However, during sporulation in chimaeras, 48.1a1 formed relatively fewer spores than 46d2. Similar trade-offs were seen in all mixes. F5 and F16 displayed an unexpected feature during sporulation; the spore-forming efficiency of either strain depended on its proportion in the initial mix in a frequency-dependent manner that was consistent with a stable equilibrium. Thus, trade-offs between different fitness-related traits contribute to the co-existence of strains. Next, I studied interactions between members of different CSM species. Several species of CSMs were isolated from the same environment (Sathe et al., 2010); a question of interest was to see if amoebae of different species came together to form a chimaeric multicellular body. Five strains (two D. purpureum and three D. giganteum) were used in this study. Amoebae of D. giganteum and D. purpureum co-aggregated. However, there were factors that caused amoebae of the two species to sort out thereafter. The extent of segregation differed between strains, a characteristic that inter-species mixes share with intra-species mixes. In conclusion, the ability of cellular slime moulds to form multiclonal social groups in the wild suggests that one should look to factors in addition to close relatedness to understand the evolution of CSM social behaviour. The existence of fitness-related trade-offs between different traits indicates that individual-level selection can also contribute to the maintenance of chimaeric social groups. Sociobiology Cooperation Evolution Dictyostelium giganteum Social Amoebae Dictyostelium purpureum D. giganteum Cellular Slime Mould (CSM) Dictyostelids Social Amoeba Moulds - Social Behaviour Molds - Social Behaviour Cellular Slime Mold Cellular Slime Moulds (CSMs) Ecology
22	Actin Tyrosine Phosphorylation in Microcysts of Polysphondylium pallidum Budniak, Aldona 15 December 2010 (has links) High osmolarity causes amoebae of the cellular slime mould Polysphondylium pallidum to individually encyst, forming microcysts. During microcyst differentiation, actin is tyrosine phosphorylated. Tyrosine phosphorylation of actin is independent of encystment conditions and occurs during the final stages of microcyst formation. During microcyst germination, actin undergoes dephosphorylation prior to amoebal emergence. Renewed phosphorylation of actin in germinating microcysts can be triggered by increasing the osmolarity of the medium which inhibits emergence. Immunofluorescence reveals that actin is dispersed throughout the cytoplasm in dormant microcysts. Following the onset of germination, actin is observed around vesicles where it co-localizes with phosphotyrosine. Prior to emergence, actin localizes to patches near the cell surface. Increasing osmolarity disrupts this localization and causes actin to redistribute throughout the cytoplasm, a situation similar to that observed in dormant microcysts. Together, these results indicate an association between actin tyrosine phosphorylation, organization of the actin cytoskeleton, and microcyst dormancy. actin dormancy germination microcyst Polysphondylium tyrosine phosphorylation cytoskeleton encystation osmolarity slime mould 0379 0410 0307
23	Actin Tyrosine Phosphorylation in Microcysts of Polysphondylium pallidum Budniak, Aldona 15 December 2010 (has links) High osmolarity causes amoebae of the cellular slime mould Polysphondylium pallidum to individually encyst, forming microcysts. During microcyst differentiation, actin is tyrosine phosphorylated. Tyrosine phosphorylation of actin is independent of encystment conditions and occurs during the final stages of microcyst formation. During microcyst germination, actin undergoes dephosphorylation prior to amoebal emergence. Renewed phosphorylation of actin in germinating microcysts can be triggered by increasing the osmolarity of the medium which inhibits emergence. Immunofluorescence reveals that actin is dispersed throughout the cytoplasm in dormant microcysts. Following the onset of germination, actin is observed around vesicles where it co-localizes with phosphotyrosine. Prior to emergence, actin localizes to patches near the cell surface. Increasing osmolarity disrupts this localization and causes actin to redistribute throughout the cytoplasm, a situation similar to that observed in dormant microcysts. Together, these results indicate an association between actin tyrosine phosphorylation, organization of the actin cytoskeleton, and microcyst dormancy. actin dormancy germination microcyst Polysphondylium tyrosine phosphorylation cytoskeleton encystation osmolarity slime mould 0379 0410 0307
24	Mechanisms of Rupture of Mucin Vesicles from the Slime of Pacific Hagfish (Eptatretus stoutii): Roles of Inorganic Ions and Aquaporin Water Channels Herr, Julia Emily 28 May 2012 (has links) Pacific hagfish (Eptatretus stoutii) slime mucin vesicles are released by holocrine secretion with membranes that remain intact until the vesicle contacts seawater and ruptures. This thesis is an investigation of the mechanisms that drive mucin vesicle rupture for mucin release. Using isolated mucin vesicles collected from the slime glands of the hagfish, I tested the effects of a variety of solutions and drugs on vesicle rupture. I found that there are two categories of mucin vesicle that differ in their sensitivity to calcium ions, and that calcium-dependent vesicle rupture was inhibited with anion channel inhibitors. I also found that vesicle swelling rate was reduced by the aquaporin inhibitor mercuric chloride. Together, these data suggest that mucin vesicle rupture is partially dependent on the movement of chloride ions from seawater through calcium-activated anion channels and the rapid influx of water through aquaporin-like proteins in the vesicle membrane. / NSERC Discovery Grant, NSERC CGSM scholarship, Canada Foundation for Innovation, Ontario Ministry of Research and Innovation hagfish slime mucin vesicle calcium-activated chloride channel aquaporin mucus ion channel
25	Tradeoffs and social behaviour in the cellular slime moulds Sathe, S. 13 April 2012 (has links) (PDF) By combining laboratory experiments with field work, I have looked at the following aspects of cellular slime mould (CSM) biology: (a) the genetic structure of social groups (fruiting bodies) in the wild and its relation to the role of large mammals as dispersal agents; (b) social behaviour in clonal, intra-species polyclonal and interspecies social groups and (c) fitness-related trade-offs with respect to life history traits as a possible mechanism for coexistence and cooperative behaviour in CSMs. The major findings of this study are as follows: (a) individuals belonging to different strains of a species, different species and genera occur in close proximity, even on a speck of soil (250µm-1mm) or the same dung pat; (b) social groups formed in the wild by Dictyostelium giganteum and D. purpureum are generally multiclonal; (c) genetically diverse strains can co-aggregate and form chimaeric social groups; (d) in chimaeric social groups, strains differ in their relative sporulation efficiencies; (e) the fact that strains co-exist in spite of this may be attributable in part to trade-offs between various fitness-related traits as can be demonstrated in the case of wild isolates of D. giganteum in pair wise mixes. The Dictyostelids or CSMs are haploid, eukaryotic, soil dwelling social amoebae with an unusual life cycle (Bonner, 1967; Raper, 1984). They exist as single cells in the presence of food (bacteria, yeast, fungal spores). Once the food is exhausted, they enter the social phase of their life cycle. Approximately 102 to 106 amoebae aggregate at a common collection point and form a starvation resistant structure called the fruiting body. In many species a fruiting body is made up of an aerial stalk of dead cells and a ball of viable spores on top. In other CSM species (not part of this study), all amoebae in a fruiting body differentiate into spores and the stalk is an extracellular secretion. The CSM life cycle raises fundamental questions related to the evolution of an extreme form of 'altruism' in the form of reproductive division of labour in social groups. The spore-stalk distinction in the CSMs is analogous to the germ-soma distinction in metazoans, although, the CSMs achieve multicellularity not by repeated divisions of a zygote but via the aggregation of many cells which may or may not be clonally related (Bonner, 1982; Kaushik and Nanjundiah, 2003). Social behaviour in the CSMs offers interesting parallels to what is seen in the social insects (Gadagkar and Bonner, 1994). The origin and maintenance of 'altruism' has been a long-standing issue in sociobiology. Because of their simple life cycle and experimental tractability, the CSMs are ideal for studying the evolutionary origin and maintenance of social behaviour, in particular of 'altruistic' behaviour. By elevating spores above soil level, stalk cells, protect them from noxious compounds and predators present in soil and also facilitate their passive dispersal. In the course of doing so they die. The death of stalk cells appears to be an extreme form of altruism. Knowledge of the genetic structure of social groups and populations including patterns of kinship is essential for modelling the evolution of 'altruism'. Thus, it is important to understand the genetic structure of CSM social groups in the wild. For this, social groups (fruiting bodies) of CSMs were isolated from undisturbed forest soil of the Mudumalai forest reserve in South India. Soil and animal dung samples were brought to the laboratory and quasi-natural social groups were generated by inoculating the samples on non-nutrient agar. The fruiting bodies from various CSM species were formed by these isolates. Since soil and dung samples were not perturbed in any way, the fruiting bodies were formed as they would have in nature. When compared to soil, dung samples contained a higher CSM diversity and more CSM propagules. The presence of CSMs in fresh animal dung makes it likely that they were transported and dispersed over long distances through the gut of these animals. Such dispersal is likely to be preceded by a thorough mixing of spores in the gut. That increases the probability of co-occurrence of different genotypes in a social group. This possibility was confirmed by genetically characterizing spores in social groups of Dictyostelium giganteum and D. purpureum collected from the wild. Random amplification of polymorphic DNA (RAPD), a simple and reliable molecular technique, was used for genotyping spores within a fruiting body. 17 fruiting bodies (8 from animal dung and 9 from soil) were studied. 15 out of 17 (9 out of 11 of D. giganteum and 6 out of 6 D. purpureum) were polyclonal; the minimum number of distinct clones in a single fruiting body was 3 to 7 (animal dung) and 1 to 9 (soil). Therefore in D.giganteum and D. purpureum, chimaeric social groups seem to be the norm. This suggests that other species of CSMs form intra-species chimaeric social groups in wild, though clonal fruiting bodies occur too. The next objective of this thesis was to test whether genetic heterogeneity had functional consequences. That is, when different strains come together in an aggregate, do they contribute equally to the reproductive (spore) and non-reproductive (stalk) pathways? Amoebae of different clones (strains) of D. giganteum or D. purpureum were mixed and developed together and the number of spores formed by each strain was counted. These experiments confirmed that strains of D. giganteum or D. purpureum can aggregate together and form chimaeric fruiting bodies. The ability to mix (measured as the frequency of chimaerism) depended on the strains used and varied from one mix to another. One strain was often found to 'exploit' the other during sporulation, that is, it formed more spores than its expected share. Despite this, strains are found in very close proximity in the soil, which raises an important question: when one strain is more efficient at sporulating than other, how can the two co-exist stably? To investigate what might lie behind the stable co-existence of strains, I studied various fitness-related traits in the life cycle of D. giganteum. They included the rate of cell division, the time taken to go through multicellular development, the efficiency of slug migration through various depths of soil and the probability of differentiation into a spore. Measurements were carried out on strains taken separately and on their pair wise mixes. Five different D. giganteum wild strains (46a3, 46d2, 48.1a1, F5 and F16) were used. All were isolated from the Mudumalai forest (India). 46a3 and 46d2 came from soil within 10 cm of each other, 48.1a1 from soil about 200m away from 46a3; and F5 and F16 from the same fruiting body (Kaushik et al., 2006; Sathe et al., 2010). Members of a pair differed significantly in the measured fitness-related traits. For example, in the case of 48.1a1 and 46d2, 48.a1 grew faster than 46d2 both individually and in a mix. After starvation, 48.1a1 formed fruiting bodies faster than 46d2; a mix of the two developed at the rate of the faster member, implying that the slower one (46d2) gained from the association with 48.1a1. During slug migration, slugs formed by 48.1a1 came up through a higher depth of soil than 46d2 slugs and did so earlier. Chimaeric slugs were like the more efficient member, 48.1a1, in terms of the maximum depth of soil that was covered, but like the less efficient member, 46d2, in terms of the time taken for slugs to be seen on the soil surface. 48.1a1 seems to have an advantage over 46d2 in all these respects. However, during sporulation in chimaeras, 48.1a1 formed relatively fewer spores than 46d2. Similar trade-offs were seen in all mixes. F5 and F16 displayed an unexpected feature during sporulation; the spore-forming efficiency of either strain depended on its proportion in the initial mix in a frequency-dependent manner that was consistent with a stable equilibrium. Thus, trade-offs between different fitness-related traits contribute to the co-existence of strains. Next, I studied interactions between members of different CSM species. Several species of CSMs were isolated from the same environment (Sathe et al., 2010); a question of interest was to see if amoebae of different species came together to form a chimaeric multicellular body. Five strains (two D. purpureum and three D. giganteum) were used in this study. Amoebae of D. giganteum and D. purpureum co-aggregated. However, there were factors that caused amoebae of the two species to sort out thereafter. The extent of segregation differed between strains, a characteristic that inter-species mixes share with intra-species mixes. In conclusion, the ability of cellular slime moulds to form multiclonal social groups in the wild suggests that one should look to factors in addition to close relatedness to understand the evolution of CSM social behaviour. The existence of fitness-related trade-offs between different traits indicates that individual-level selection can also contribute to the maintenance of chimaeric social groups. [SDV] Life Sciences [SDV] Sciences du Vivant Cooperation cellular slime moulds development evolution kin selection coexistance
26	Estudo de amostras de Staphylococcus coagulase-negativa quanto a formação de biofilme Bernardi, Adilson César Abreu [UNESP] 13 December 2005 (has links) (PDF) Made available in DSpace on 2014-06-11T19:32:55Z (GMT). No. of bitstreams: 0 Previous issue date: 2005-12-13Bitstream added on 2014-06-13T19:22:47Z : No. of bitstreams: 1 bernardi_aca_dr_arafcf.pdf: 1525508 bytes, checksum: c65f0bdce77e95dac615f5ee33dd6287 (MD5) / Universidade Estadual Paulista (UNESP) / Os Staphylococcus coagulase-negativa, particularmente, os Staphylococcus epidermidis são a causa mais freqüente de infecções relacionadas ao cateter por sua habilidade em aderir a uma superfície e entre si (aderência intercelular) formando biofilme em multicamadas sobre superfícies de polímeros. O objetivo do presente estudo foi avaliar cepas hospitalares de Staphylococcus coagulasenegativa isoladas de cateteres intravenosos, quanto à resistência a oxacilina, produção de slime, aderência ao poliestireno, habilidade de formar biofilme sobre superfícies abióticas (cateter esterilizado) e a presença de genes icaAD. Na presente pesquisa, a presença de icaA e icaD foi determinada pelo método PCR, em uma coleção de 27 amostras Staphylococcus coagulase-negativa (10 Staphylococcus epidermidis, 4 S. haemolyticus, 2 S. hominis, 2 S. lugdunensis, 1 S. saprophyticus, 1 S. schleiferi, 2 S. xylosus e 4 S. warneri). Os genes icaAD foram detectados em dez cepas S. epidermidis... / Coagulase-negative Staphylococcus, particularly, Staphylococcus epidermidis are frequent cause of infections associated with catheters and is attributed to the attachment ability on a surface and each other (intercellular adhesion) forming a multilayered biofilm on polymeric surfaces. The objective of the present study was to evaluate coagulase-negative Staphylococcus strains isolated from intravenous catheters by oxacillin resistance, slime production (qualitative method) and spectrophotometric assay (quantitative method), ability to form biofilm on abiotic surfaces (steriled catheter) and the presence of icaAD genes. In the present study icaA and icaD were determined by PCR method, in a collection of 27 coagulasenegative Staphylococcus (10 Staphylococcus epidermidis, 4 S. haemolyticus, 2 S. hominis, 2 S. lugdunensis, 1 S. saprophyticus, 1 S. schleiferi, 2 S. xylosus and 4 S. warneri). The icaA genes were detected in nine S. epidermidis and icaD in ten. The slime-producing ability was determined by culture on Congo red agar plates in which slime-producing strains formed black colonies in 10 S. epidermidis, 4 S.haemolyticus, 4 S. warneri, 2 S. xylosus and 1 S. chromogenes, while nonslimeformingones develop red colonies. The quantitative assay of coagulase-negative Staphylococcus was observed in 19 strains, including: 10 S. epidermidis, 3 S.haemolyticus, 3 S. warneri, 2 S. xylosus, 1 S. chromogenes. The ability of coagulasenegative Staphylococcus to form biofilm embedded in an amorphous substance wasobserved by scanning electronic microscope on abiotic surface in 10 S. epidermidis,3 S. haemolyticus, 2 S. hominis, 2 S. lugdunensis, 1 S. saprophyticus, 1 S. schleiferi,2 S. xylosus and 3 S. warneri. The oxacillin resistance was observed in 9 strains S.epidermidis, 3 S. haemolyticus, 3 S. warneri, 1 S. xylosus and 1 S. chromogenes. All strains of staphylococci were susceptible... (Complete abstract, click eletronic address below) Microbiologia médica Staphyloccocus epidermis Slime Operon ica Fatores de virulência Virulence factors
27	Jag är Fucking Phoenix Brodrej, Pelerin January 2016 (has links) Kvarnen står i ett hus som brinner.Den lila gudinnan är också där, hon blir till aska. Allt var i det där huset och när jag skriver allt så menar jag det. Egentligen är essän det enda som klarade sig. Den låg i ett mail. Vad gör en häxa utan sin dolk, sitt ljus? Hon ger sig inte, hon blir starkare, hon får blodad tand.Jag måste använda häxkrafterna nu, mina naglar är längre än någonsin.Jag hinner inte samla längre, jag minns vad jag la i kvarnen så jag kan inte göra annat än mala nu. Simon säger att jag är Fucking Phoenix! / Jag fick börja om på min masterutställning efter branden i grafikhuset på Skeppsholmen där jag hade min ateljé. Jag tänkte mycket på förvandling, att vara en fågel Fenix, att göra sig starkare med hjälp av saker en älskar. Det blev temat för utställningen och essän. glitter witchcraft förvandling naglar häxa gudinna smink flow slime badkar syster vatten sjöjungfru brand Humanities and the Arts Humaniora och konst
28	Pretreatment Methods for Manganese Containing Anode Sludge Stenman, Johan January 2017 (has links) This master thesis work examines whether it is possible to separate lead from an electrolytic sludge rich in manganese using pyrometallurgical treatment, and also attempts to determine the optimum process parameters for such a treatment. It also includes a theoretical study of the possible applications for lead and manganese, as well as thermodynamic calculations predicting the behaviour of the material at increasing temperatures. The experimental work completed includes characterisation and agglomeration of the raw material, as well as tests in a chamber furnace and a rotary furnace. The anode sludge was characterised using chemical analysis, XRD, SEM and PSD. The anode sludge was agglomerated into pellets using either both bentonite and water, or only water as binder. The smaller scale tests in the chamber furnace examined the impact of several variables on lead removal. These variables included type and amount of reduction agent used, temperature, and whether the anode sludge was added as untreated material or pellets. The most promising of these results were further tested in the rotary furnace at a slightly larger scale. The variables used for the rotary furnace tests were amount of reduction agent added, whether the anode sludge was added as untreated material or pellets, and whether the reduction agent was added at the start of or during the experiment. All samples were sent for chemical analysis, and selected samples were further analysed using XRD and SEM. The conclusions drawn from the results of the thermodynamic calculations and experimental work are as follows: In the untreated anode sludge the primary phases are MnO2, CaSO4, and (Pb,Sr)SO4. The anode sludge can be agglomerated into pellets, with or without added binder. After treatment the primary phases present are MnO and (Ca,Sr)2SiO4. Lead is present as small separate grains. The most effective treatment method should adhere to the following parameters:Use of a rotating furnace. Anode sludge added in the form of pellets, to simplify materials handling. Temperature of 1400-1500 °C. Reduction agent added in batches after initial smoke formation has stopped. Total addition of reduction agent should be 10 wt% of anode sludge. Significant weight loss occurs during treatment. The amount of reduction agent added to the anode sludge has the greatest effect on the removal of lead and zinc. Charcoal is a potential candidate for a renewable reduction agent, but leads to increased weight loss. It is possible to separate lead from the manganese anode sludge using pyrometallurgical treatment, down to 100 ppm. Zinc can also be separated, down to 600 ppm. / Detta examensarbete undersöker huruvida det är möjligt att separera bly från ett anodslam rikt i mangan med hjälp av pyrometallurgiska behandlingsmetoder, och försöker även avgöra de optimala processparametrarna för en sådan behandling. Arbetet inkluderar även en teoristudie av möjliga användningsområden för bly och mangan, samt termodynamiska beräkningar som förutser materialets beteende vid ökande temperaturer. Det experimentella arbetet som utförts inkluderar karakterisering och agglomerering av råmaterialet, samt försök i en kammarugn och en rullugn. Anodslammet karakteriserades med hjälp av kemisk analys, XRD, SEM, och partikelstorleksfördelning. Anodslammet agglomererades till pellets med antingen bentonit och vatten eller bara vatten som bindemedel. Försöken i mindre skala i kammarugnen undersökte hur flera variabler påverkade blyavdrivningen. Dessa variabler inkluderade typ och mängd av reduktionsmedel som tillsattes, temperatur, och huruvida anodslammet som användes var obehandlat material eller pellets. De mest lovande av dessa resultat användes för vidare försök i rullugnen i något större skala. Variablerna som undersöktes vid rullugnsförsöken var mängd reduktionsmedel som tillsattes, huruvida anodslammet som användes var obehandlat material eller pellets, samt huruvida reduktionsmedlet tillsattes vid start eller under försökets gång. Alla prover skickades för kemisk analys, och utvalda prover analyserades ytterligare med XRD och SEM. Slutsatserna som dragits utifrån resultaten av de termodynamiska beräkningarna och det experimentella arbetet är som följande: I det obehandlade anodslammet är de primära faserna MnO2, CaSO4, och (Pb,Sr)SO4. Anodslammet kan agglomereras till pellets. Efter behandling är de primära faserna i materialet MnO och (Ca,Sr)2SiO4. Kvarvarande bly är närvarande som små separata korn. Den mest effektiva behandlingsmetoden bör använda följande parametrar: Användning av en roterande ugn. Anodslam bör tillsättas i form av pellets för att underlätta materialhantering. Temperatur mellan 1400-1500 °C. Reduktionsmedel tillsatt i omgångar efter att initial rökbildningen avstannat. Total tillsats av reduktionsmedel bör vara 10 vikt% av anodslammets vikt. Signifikanta viktförluster under behandling. Mängden tillsatt reduktionsmedel är den faktor som har störst effekt på avlägsnandet av bly och zink. Träkol är en potentiell kandidat för ett förnyelsebart reduktionsmedel, men orsakar ökade viktförluster. Det är möjligt att separera bly från mangan med hjälp av pyrometallurgiska metoder, ned till 100 ppm bly. Zink kan också separeras, ned till 600 ppm. Manganese Zinc Lead Strontium Reduction Anode Sludge Slime Metallurgy Pyrometallurgy Chamber Rotary Furnace Agglomeration Chemical Engineering Kemiteknik
29	Reinforcement in Biology : Stochastic models of group formation and network construction Ma, Qi January 2012 (has links) Empirical studies show that similar patterns emerge from a large number of different biological systems. For example, the group size distributions of several fish species and house sparrows all follow power law distributions with an exponential truncation. Networks built by ant colonies, slime mold and those are designed by engineers resemble each other in terms of structure and transportation efficiency. Based on the investigation of experimental data, we propose a variety of simple stochastic models to unravel the underlying mechanisms which lead to the collective phenomena in different systems. All the mechanisms employed in these models are rooted in the concept of selective reinforcement. In some systems the reinforcement can build optimal solutions for biological problem solving. This thesis consists of five papers. In the first three papers, I collaborate with biologists to look into group formation in house sparrows and the movement decisions of damsel fish. In the last two articles, I look at how shortest paths and networks are constructed by slime molds and pheromone laying ants, as well as studying speed-accuracy tradeoffs in slime molds' decision making. The general goal of the study is to better understand how macro level patterns and behaviors emerges from micro level interactions in both spatial and non-spatial biological systems. With the combination of mathematical modeling and experimentation, we are able to reproduce the macro level patterns in the studied biological systems and predict behaviors of the systems using minimum number of parameters. reinforcement in biology merge and split model preferential attachment reinforced random walk network construction shortest path problem transport networks ant algorithm slime mould physarum polycephalum speed-accuracy tradeoff.
30	Investigating Metapopulation Responses to Landscape-Level Habitat Changes Jakob Goldner (11824130) 19 December 2021 (has links) The study of landscape structure and configuration is firmly established as integral to the continued advancement of ecology. The configuration of resource patches can have far-reaching implications for biodiversity, metapopulation dynamics, community structure, and habitat quality. Human activities, such as forestry, agriculture, and residential construction alter patch configuration by breaking larger patches into smaller fragments. This frequently results in pronounced, unforeseen consequences for species. The fragmentation and shrinking of habitat patches can lead to changes in the environmental conditions within the remaining patches (e.g., degradation), prompting responses from local populations. These responses can, in turn, cause changes to the metapopulation structure on large spatial scale.<br>I examined the relationship between the degree of habitat fragmentation (edge density), and forewing lengths of the ebony jewelwing damselfly (Calopteryx maculata Beauvois, Odonata: Calopterygidae). I used correlated random walks to determine the biologically relevant landscape area over which forest fragmentation was calculated. Then, I used Moran’s I to determine the spatial scale of wing length response to fragmentation. I found that wing lengths increased with edge density. I also found that wing lengths were spatially autocorrelated at distances below 5 Km. These findings suggest that damselflies adapt to changes in forest fragmentation at a relatively small spatial scale.<br>Next, I assessed the slime mold Physarum polycephalum’s usefulness as a microcosm of dispersal in fragmented landscapes. Slime mold plasmodia were placed in dishes with oat patches of varying sizes and distances. The probability of each patch type being colonized first was compared to predictions of patch occupancy based on C. maculata. Patches that were nearer or larger were likely to be colonized before patches that were more distant, or smaller. Observed patch occupancy matched model predictions when only patch distance was varied, but not when patch size was varied. These results suggest that P. polycephalum has the potential to serve as a useful microcosm of dispersal in patchy landscapes. However, more testing is needed to develop the microcosm system. <br>Finally, a lesson plan was developed to teach high school students about the concepts of landscape ecology and connectivity. An emphasis was placed on using active learning techniques, which have been demonstrated to result in greater understanding than traditional lecture formats. The lesson plan incorporates an education boardgame, Humans & Habitats, that I developed to illustrate how the conflicting goals of resource managers impact habitat connectivity. It also incorporates a scientific inquiry activity that uses P. polycephalum to test predictions about the effect of altered connectivity. The lesson plan and materials will be available to members of the public, free of charge.<br><br> Landscape Ecology Landscape ecology dispersal capacity deforestation local adaptation spatial scale metapopulation metapopulation model Physarum polycephalum slime mold model landscape landscape microcosm patch connectivity active learning lesson plan educational game sustainability education connectivity

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