ABSTRACT
Thermoacidophiles can exist in a state of dormancy both in moderate temperatures and even in cold conditions in heap leaching. Sulphide mineral ores such as chalcopyrite produce sulfuric acid when exposed to the air and water. The produced sulfuric acid leads to the decrease of pH and exothermic reactions in heap leaching causing the temperature to increase up to 55 °C and the activation of thermoacidophilic microorganisms. The aim of the present study was to isolate indigenous extreme thermoacidophilic microorganisms at ambient temperature from Sarcheshmeh Copper Complex, to adapt them to the high pulp density of a chalcopyrite concentrate, and to determine their efficiency in chalcopyrite bioleaching in order to recover copper. In this study samples were collected at ambient temperature from Sarcheshmeh Copper Complex in Iran. Mixed samples were inoculated into the culture medium for enrichment of the microorganisms. Pure cultures from these enrichments were obtained by subculture of liquid culture to solid media. Morphological observation was performed under the scanning electron microscope. Isolates were adapted to 30% (w/v) pulp density. For the bioleaching test, the experiments were designed with DX7 software. Bioleaching experiments were carried out in Erlenmeyer flasks and a stirred tank reactor. The highest copper recovery in Erlenmeyer flasks was 39.46% with pulp 15%, inoculums 20%, size particle 90 pm and 160 rpm. The lowest recovery was 3.81% with pulp 20%, inoculums 20%, size particle 40 pm and 140 rpm after 28 days. In the reactor, copper recovery was 32.38%. Bioleaching residues were analyzed by the X-ray diffraction (XRD) method. The results showed no jarosite (KFe3(SO4)2(OH)6) had formed in the bioleaching experiments. It seems that the antagonistic reactions among various species and a great number of planktonic cells in Erlenmeyer flasks and the stirred tank reactor are the reasons for the low recovery of copper in our study.
Los microorganismos termoacidófilos pueden estar en estado latente tanto a temperatura moderada como baja, en lixiviación en pilas. Los minerales sulfurosos, como la calcopirita, producen ácido sulfúrico cuando se exponen al aire y al agua. El ácido sulfúrico producido conduce a la disminución del pH y a reacciones exotérmicas durante la lixiviación en pilas, lo que hace que la temperatura aumente hasta 55 °C y se activen los microorganismos termoacidófilos. El objetivo del presente estudio fue aislar del complejo de cobre Sarchesh-meh (Irán) microorganismos termoacidófilos extremos que proliferan a temperatura ambiente e investigar su adaptación a la alta densidad de pulpa del concentrado de calcopirita, así como su eficiencia para biolixiviarese mineral, con el objeto de recuperar el cobre. Se recogieron muestras a temperatura ambiente del citado complejo, y luego muestras mixtas se inocularon en un medio de cultivo de enriquecimiento. A partir de estos enriquecimientos, mediante el subcultivo del cultivo líquido a medio sólido, se obtuvieron cultivos puros. La observación morfológica se realizó bajo microscopio electrónico de barrido. Los aislados estaban adaptados al 30% p/v de densidad de pulpa. Para la prueba de biolixiviación, los experimentos fueron diseñados con el software DX7. Los experimentos de biolixiviación se llevaron a cabo en Erlenmeyers y en un reactor tanque con agitación. La mayor recuperación de cobre en los Erlenmeyers fue del 39,46% y se obtuvo con la pulpa al 15%, un inóculo del 20%, un tamaño de partícula de 90 µm y una agitación de 160 rpm. La menor recuperación fue del 3,81% y se obtuvo con la pulpa al 20%, un inóculo del 20%, un tamaño de partícula de 40 µm y una agitación de 140 rpm, después 28 días. En el reactor, la recuperación del cobre fue del 32,38%. El análisis de difracción de rayos X (XRD) no mostró que se formara jarosita (KFe3-#91;SO4-#93;2-#91;OH-#93;6) en los experimentos de biolixiviación. Dicha técnica sirve para determinar la estructura cristalina de una sustancia desconocida. Al parecer, las reacciones antagónicas entre las diversas especies y el mayor número de células planctónicas en los Erlenmeyers y en el reactor fueron las causas de la baja recuperación de cobre observada en este estudio.
Subject(s)
Percolation/analysis , Chemical Reactions/analysis , Copper/economics , Causality , Adaptation to Disasters , Hydrogen-Ion ConcentrationABSTRACT
The aim of this work was to investigate the state of fluoride at the surface of fluoridemodified titanium implants, and to provide information to support or discard the hypothesis that fluoride ion participates in the osseointegration of implants. Titanium is coated with a 2-10 nm thick layer of stable and adherent TiO2, which reacts with fluoride as a function of the anion concentration. Under present experimental conditions, the half-life of the reaction is about 2 minutes at 17 °C. The stoichiometry of the reaction Ti:F is 0.46 ± 0.03, which do not differs significantly from 0.5, the ratio inferred from the reaction between sodium fluoride and TiO2: 3 TiO2 + 6 NaF Na2 TiF6 + 2 Na2 TiO3 . The reaction proceeds as a function of the fraction of anionic fluoride concentration, which increases from a minimum at pH 1 to a maximum close to pH 6. The number of fluoride mmoles that react with TiO2 grows exponentially as a function of fluoride concentration, towards a maximum at 0.24 M fluoride. According to literature reports, potassium hexafluorotitanate is insoluble in water and it decomposes by heating at 780 °C, indicating a high formation constant. It is concluded that the hexafluorotitanate would not ionize to provide fluoride ion to the implant-bone environment and to promote growth and differentiation of osteoblasts. The effect of fluoride on the surface of titanium sheet was investigated under SEM, showing that the titanium sheet surface is roughened and electron dispersive spectroscopic microanalysis indicated that fluorine is included in the TiO2 layer. (AU)
El objetivo de este trabajo fue investigar el estado del flúor en la superficie de implantes de titanio tratados con fluoruro de sodio y obtener información para descartar o apoyar la hipótesis de su participación en el proceso de osteo-integración. El titanio está recubierto con una capa estable y adherente de TiO2, de 2-10 nm de espesor, que reacciona con el fluoruro en función de la concentración del anión. En las condiciones experimentales utilizadas el tiempo de vida media de la reacción es de 2 minutos at 17 ºC, pH 5,5. La reacción procede en función de la fracción de fluoruro iónico de la concentración total de fluoruro, que aumenta de un mínimo a pH 1 a un máximo a pH 6. El número de µmoles de fluoruro que reaccionan con TiO2 crece exponencialmente en función de la concentración del anión, hacia un máximo a 0,244 M. La relación estequiométrica de la reacción Ti:F es 0.46 ± 0.03 no difiere significativamente de 0.5; relación inferida de la reacción: 3 TiO2 + 6 NaF Na2 TiF6 + 2 Na2 TiO3. Como el hexafluorurotitanato de potasio es insoluble en agua y tiene una elevada constante de formación (se descompone por calentamiento a 780 ºC), se concluye que no se disociará para proveer fluoruro a las células óseas en contacto con el implante. La observación al microscopio electrónico de barrido y el análisis por espectroscopía de dispersión de rayos X de la superficie de un trozo de hoja de titanio tratado con solución de NaF a pH 3.5, indicaron aumento de la rugosidad y presencia de flúor en la capa de TiO2. (AU)
Subject(s)
Titanium/chemistry , Osseointegration/physiology , Fluorides/chemistry , Prostheses and Implants , Chemical Reactions/analysis , Bone-Anchored ProsthesisABSTRACT
O objetivo deste trabalho foi determinar o tempo ótimo de escarificação das sementes de Senna alata em ácido sulfúrico e verificar o efeito da temperatura, em condição de luz e escuro, na germinação de sementes dessa espécie. As sementes foram imersas em ácido sulfúrico concentrado por períodos de 0, 15, 30 e 60 minutos, e o teste de germinação realizado em BOD a 25ºC, utilizando quatro repetições de 50 sementes em cada período de tempo, sendo o delineamento estatístico inteiramente casualizado com 4 tratamentos. No segundo experimento, para verificar o efeito da temperatura e da condição de luz mais adequada a germinação, utilizou-se temperaturas de 10 a 45ºC, com intervalos de 5ºC, em condição de luz fluorescente branca ou escuro contínuo (gerbox preto). Utilizou-se o delineamento experimental inteiramente casualizado, disposto em esquema fatorial 8x2, com 4 repetições, de 50 sementes cada. Em todos os testes as avaliações da porcentagem e índice de velocidade de germinação foram feitas diariamente, durante 10 dias, onde as sementes foram consideradas germinadas quando apresentaram 2 mm de raiz. Os dados foram submetidos à análise de variância e as médias comparadas pelo teste de Tukey a 5 por cento de probabilidade. A escarificação do tegumento com ácido sulfúrico durante 60 minutos, foi ideal para as sementes de Senna alata, por proporcionar maiores valores na porcentagem e velocidade de germinação. A germinação ocorre entre 15 e 40ºC, sendo consideradas fotoblásticas neutras entre 20 e 40ºC e fotoblásticas negativas preferenciais a 15ºC. O melhor desempenho germinativo foi obtido nas temperaturas de 25, 30 e 35ºC, onde ocorreram maior porcentagem e velocidade de germinação.
The aim of this study was to establish the optimum scarification time for Senna alata seeds in sulfuric acid, as well as to verify the effect of temperature on seed germination for this species under conditions of light and darkness. Seeds were immersed in concentrated sulfuric acid for periods of 0, 15, 30 and 60 minutes, and the germination test was carried out in a BOD chamber at 25ºC, using four replicates of 50 seeds for each time period. Experimental design was completely randomized with 4 treatments. In the second experiment, temperatures from 10 to 45ºC, with 5ºC intervals, were used under conditions of fluorescent white light or continuous darkness (black "gerbox") in order to verify the temperature effect and the most suitable light condition for germination. Experimental design was completely randomized, in an 8x2 factorial arrangement, with 4 replicates of 50 seeds each. In all tests, germination percentage and speed index were daily evaluated for 10 days. Seeds were considered germinated when the radicle length was 2 mm. Data were subjected to analysis of variance and means were compared by Tukey's test at 5 percent significance. The tegument scarification with sulfuric acid for 60 minutes was optimal for Senna alata seeds since it led to higher values of germination percentage and speed. Germination occurs between 15 and 40ºC, and seeds are considered neutral photoblastic between 20 and 40ºC and negative photoblastic especially at 15ºC. The best germination performance was observed at 25, 30 and 35ºC, at which germination percentage and speed were higher.
Subject(s)
Germination , Hot Temperature , Photic Stimulation , Seeds/growth & development , /growth & development , Chemical Phenomena/methods , Outflow Velocity Measurement/methods , Chemical Reactions/analysis , Sulfuric AcidsABSTRACT
Objetivou-se com este trabalho estudar a metodologia do teste de tetrazólio para sementes de Amburana cearensis (Allemão) A.C. Smith, determinando as melhores condições de pré-umedecimento, bem como temperatura, período de coloração e concentração da solução de tetrazólio. Avaliou-se a coloração das sementes intactas e escarificadas (lixadas), ambas com tegumento, diretamente na solução de tetrazólio nas concentrações de 0,025; 0,050; 0,075 e 1 por cento a 35 e 40ºC, por 12 e 24h no escuro. Verificou-se o pré-umedecimento para retirar o tegumento utilizando-se sementes intactas e escarificadas, as quais foram imersas diretamente em água e submetidas a embebição em papel toalha e por 12, 24, 36 e 48 horas em temperaturas de 35 e 40ºC. Após a determinação do método para retirar o tegumento os embriões foram submetidas à coloração em solução de tetrazólio nas concentrações de 0,025; 0,050; 0,075 e 1 por cento. Com os resultados obtidos verificou-se a necessidade da retirada total do tegumento para que ocorra a coloração e que a temperatura de 40ºC é prejudicial para a embebição no pré-umedecimento. O teste de tetrazólio nas sementes de A. cearensis deve ser realizado com o pré-umedecimento das sementes escarificadas (lixadas) e imersas diretamente em água por 24 horas, na temperatura de 35ºC, para posterior retirada total do tegumento. E para atingir a coloração ideal os embriões devem ser imersos em solução de tetrazólio a 0,05 por cento por 3 horas, a 40ºC.
This work aimed to evaluate the methodology of tetrazolium test in Amburana cearensis (Allemão) A.C. Smith seeds, establishing the best pre-moistening conditions, as well as temperature, coloration period and tetrazolium solution concentration. The coloration of intact and scarified (sanded) seeds, both with tegument, was directly evaluated in tetrazolium solution at the concentrations of 0.025; 0.050; 0.075; and 1 percent, at 35 and 40ºC, for 12 and 24 h in the dark. Pre-moistening to remove the tegument was evaluated by using intact and scarified seeds, which were directly immersed in water and subjected to imbibition in paper towel for 12, 24, 36, and 48 h at 35 and 40ºC. After establishing the method to remove the tegument, embryos were subjected to coloration in tetrazolium solution at the concentrations of 0.025; 0.050; 0.075; and 1 percent. Based on the obtained results, the complete tegument removal is needed for coloration; besides, the temperature of 40ºC is harmful for imbibition during pre-moistening. The tetrazolium test in A. cearensis seeds should be performed including pre-moistening through direct immersion of scarified (sanded) seeds in water for 24h at 35ºC for later complete tegument removal. To achieve the ideal coloration, embryos must be immersed in tetrazolium solution at 0.05 percent for 3h at 40ºC.