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41	Contribuição para o conhecimento de Collembola entomobryomorpha (Insecta) do Parque Nacional da Tijuca, Rio de Janeiro, Brasil Mendonça, Maria Cleide de January 1981 (has links) Submitted by Alberto Vieira (martins_vieira@ibest.com.br) on 2017-09-15T23:52:09Z No. of bitstreams: 1 200398.pdf: 30212230 bytes, checksum: c1e5b6d5562f2b0f2070864d59b773ca (MD5) / Made available in DSpace on 2017-09-15T23:52:09Z (GMT). No. of bitstreams: 1 200398.pdf: 30212230 bytes, checksum: c1e5b6d5562f2b0f2070864d59b773ca (MD5) Previous issue date: 1981 / CAPES / Os colêmbolos Entomobryomorpha do Parque Nacional da Tijuca são estudados taxonomicamente, e quanto a sua distribuição. O material foi coletado em 11 localidades diferentes da Floresta da Tijuca, no período de fevereiro de 1979 a fevereiro de 1980, perfazendo um total de 60 amostras com 31.403 exemplares. Selecionamos destas amostras 20 espécies, por serem as mais frequentes ou as mais característica, sendo uma reconhecida como nova para a Ciência. Baseado na morfologia das espécies, elaboramos uma chave para identificação da fauna local. Fornecemos também a terminologia usada para os colêmbolos em geral. Além de uma caracterização pormenorizada para cada espécie que nos permitiu observar novos caracteres registramos a ocorrência geográfica em escala mundial, e comentamos aspectos taxonômicos e ecológicos pertinentes ao material examinado e sua área de ocorrência. / Taxonomic and distributional study of the springtails belonging to the suborder Entomobryomorpha from Parque Nacional da Tijuca is presented. Sixty samples with 31.403 specimens were collected at eleven different localities from February 1979 through February 1980. Twenty species, incluing one not previously described were selected based on their occurrence and frequency. Based on the morphology of the species we constructed an identification key for the Entomobryomorpha of the local fauna, The terminology usually used for springtails, is also given. For each species besides careful characterization, including overlooked characters a survey of its know geographical distribution, and comments on its taxonomy and ecology is also given. Collembola entomobryomorpha Insetos Colêmbolos
42	Taxonomia e Distribuição de Collembola Poduromorpha da Restinga de Itaipuaçu, Maricá, RJ / Taxonomy and Distribution of Collembola Poduromorpha from Restinga of ltaipuaçu, Maricá, RJ Fernandes , Liliane Henriques 20 June 2001 (has links) Submitted by Alberto Vieira (martins_vieira@ibest.com.br) on 2018-01-18T20:57:30Z No. of bitstreams: 1 543145.pdf: 10739381 bytes, checksum: 99867a503494bede5342fd4ba5cabf8f (MD5) / Made available in DSpace on 2018-01-18T20:57:31Z (GMT). No. of bitstreams: 1 543145.pdf: 10739381 bytes, checksum: 99867a503494bede5342fd4ba5cabf8f (MD5) Previous issue date: 2001-06-20 / CAPES / FAPERJ / No período de maio de 1995 a abril de 1996 foram realizadas amostras mensais de folhiço/solo em três áreas da restinga de Itaipuaçu: 1O cordão arenoso, 2O cordão arenoso e área alagável. De 14.134 colêmbolos coletados, 5.556 pertenceram à Ordem Poduromorpha, distribuídos em 3 famílias, 6 subfamílias, 15 gêneros e 20 espécies. Um estudo morfológico detalhado destes táxons permitiu o reconhecimento de seis espécies novas. A distribuição geográfica de algumas espécies foi ampliada. A análise de correspondência e a regressão múltipla aplicada à matriz de frequência dos táxons mostraram que a umidade do solo, a precipitação e a temperatura foram os componentes que mais influenciaram na distribuição espacial e temporal das comunidades analisadas. Estes resultados também mostraram uma nítida separação destas áreas no que se refere à estrutura e a composição da fauna de Poduromorpha. / From May 1995 to April 1996 monthly samples of litter/soil were taken in three areas at restinga of Itaipuaçu: outer sandy ridge, inner sandy ridge and swamp area. From the 14.134 collected springtails, 5.556 belonged to the Order Poduromorpha, distributed among 3 families, 6 subfamilies, 15 genera and 20 species. The detailed morphological study of these taxa enabled to recognize six new species. The geographical distribution of some species was extended. The correspondence analysis and the multiple regression tests applied to the frequency matrix of taxa showed that the soil moisture, rainfall and temperature were the components that most affected the spatial and temporal distribution of the analyzed communities. These results also showed that the three communities have a distinctive structure and composition of Poduromorpha fauna. CNPQ::CIENCIAS BIOLOGICAS::ZOOLOGIA Distribuição espaço-temporal Restinga Taxonomia Poduromorpha Collembola
43	Effects of wildfire and prescribed burning on soil fauna in boreal coniferous forests / Malmström, Anna, January 2006 (has links) (PDF) Diss. (sammanfattning) Uppsala : Sveriges lantbruksuniversitet, 2006. / Härtill 4 uppsatser.
44	Assembly processes in soil animal communities: Integrating phylogeny and trait-based approaches Chen, Ting-Wen 26 January 2018 (has links) No description available. 333 577 community assembly soil fauna community phylogenetics springtail comparative method phylogeny trait Collembola phylogenetic signal Ökologie {Biologie} (PPN619463619)
45	Genetic diversity of sexual and parthenogenetic soil living arthropods (Collembola) in Europe: colonization patterns, pre-glacial diversifications and founder effects / Genetic diversity of Collembola in Europe von Saltzwedel, Helge 18 March 2016 (has links) No description available. 333 577 Ökologie {Biologie} (PPN619463619)
46	The soil food web of temperate deciduous forests: litter and root resources as driving factors, and soil fauna effects on ecosystem processes Grubert, Diana 04 April 2016 (has links) No description available. 333 577 soil food web aboveground belowground interactions microorganisms mesofauna Collembola earthworms soil fauna interactions PLFA SIR resource identity and diversity biodiversity Ökologie {Biologie} (PPN619463619)
47	Teores de elementos potencialmente tóxicos em solos de uma bacia hidrográfica e avaliação de risco à saúde humana / Watershed soils contents of potentially toxics elements in soils from an watershed and human health risk assessment Silva, Evandro Barbosa da 23 April 2013 (has links) A contaminação dos solos por elementos potencialmente tóxicos (EPTs) provoca alterações na estrutura e no funcionamento dos ecossistemas, além de oferecer riscos à saúde pública. Os EPTs estão presentes naturalmente no ambiente, sendo constituintes de rochas e sedimentos. Entretanto, atividades antropogênicas como emissões industriais, uso de efluentes urbanos, dejetos de animais, biossólidos, fertilizantes e defensivos agrícolas podem contribuir para aumento da concentração dos EPTs. O solo é um dos principais meios de exposição dos EPTs aos seres humanos. Logo, é importante quantificar os teores dos EPTs nos solos e sua distribuição na microbacia para poder avaliar o risco a saúde humana. Os efeitos dos elementos tóxicos que chegam ao solo sobre a diversidade e funcionalidade da biota podem ser avaliados por meio de testes ecotoxicológicos. Alguns organismos são bons indicadores ambientais por participarem de processos biológicos importantes do solo. Os principais organismos utilizados são os colêmbolos, artrópodes terrestres com alta diversidade e abundância, sendo encontrado em todos os biomas. Nesse estudo, quantificaram-se os teores de Arsênio (As), Cádmio (Cd), Cobalto (Co), Cobre (Cu), Cromo (Cr), Chumbo (Pb), Níquel (Ni) e Zinco (Zn) em amostras de 15 solos da microbacia do Rio Guamium, localizada em Piracicaba, São Paulo. Foi realizado experimento em casa de vegetação com alface (Lactuca sativa L.), pepino (Cucumis sativus L.), beterraba (Beta vulgaris L.) e rúcula (Eruca sativus Mill.) para avaliar o risco a saúde humana. Foi avaliado também o efeito da aplicação de doses de As na reprodução dos colêmbolos. Para tanto, foram coletadas amostras de solos nas profundidades 0 - 0,1; 0,1 - 0,2; 0,2 - 0,3; 0,3 - 0,4; 0,4 - 0,6; 0,6 - 0,9 e 0,9 - 1,2 m. Foi realizada a extração dos EPTs pelo método EPA 3051a (0,5 g de solo + 9 ml HNO3 + 3 ml HCl com digestão assistida por forno microondas). Os EPTs que apresentaram as maiores concentrações foram o As (3 pontos) e Cu (1 ponto), sendo as concentrações superiores ou iguais ao valor de prevenção estabelecido pelo órgão ambiental paulista (Cetesb). O As apresentou elevado risco carcinogênico, enquanto o Cu apresentou risco à saúde humana apenas quando 100 % dos vegetais consumidos eram provenientes da área com elevado teor de Cu, sendo este o cenário mais restritivo. Houve diferença na disponibilidade de As entre o solo natural e o solo artificial tropical (SAT), composto por areia, caulinita e pó de fibra de coco. O SAT apresentou alta disponibilidade de As o que reduziu a taxa de reprodução dos colêmbolos. No SAT a LOEC (Lowest Observed Effect Concentration) foi 0,25 mg kg-1 e a NOEC (No Observed Effect Concentration) < 0,25 mg kg-1. No solo natural não foi possível determinar a NOEC, enquanto a LOEC foi 8,41 mg kg-1. / Soil contamination by potential toxics elements (PTEs) can change the ecosystem structure, its function and can cause risk to human health. PTEs occur naturally in the environment; however human activities such as industrial emissions, urban sewage, animal waste, biosolids, fertilizers and pesticides can increase their concentration. Soil is one of the main pathways to human exposure, so it is important to evaluate the contents of PTEs in soils and their distribution in the watershed in order to assess the human health risk. The effects of PTEs that reach the soil on the diversity and functionality of microorganisms can be evaluated by ecotoxicological tests. Organisms that take part of the biological process can be used as environment quality indicators. One of them is the springtails (Collembola) that are wide spread and have high diversity, being found in all ecosystems. In this study, we evaluated the Arsenic (As), Cadmium (Cd), Cobalt (Co), Copper (Cu), Chromium (Cr), Lead (Pb), Nickel (Ni) and Zinc (Zn) contents in 15 soil from Guamium watershed, located in Piracicaba, state of Sao Paulo, Brazil. To assess the human health risk lettuce (Lactuca sativa L.), cucumber (Cucumis sativus L.), sugar beet (Beta vulgaris L.) and rocket (Eruca sativus Mill.) were cultivated under greenhouse conditions. The effect of As rates on collembola reproduction was also evaluated. Soil samples were collected in the following depths: 0 - 0.1; 0.1 - 0.2; 0.2 - 0.3; 0.3 - 0.4; 0.4 - 0.6; 0.6 - 0.9 e 0.9 - 1.2 m. Contents of PTEs were obtained after microwave extraction by EPA 3051a method (0.5 g soil + 9 mL HNO3 + 3 mL HCl). As and Cu had the highest contents, and their concentration were close or higher than prevention value established by Sao Paulo state environmental agency (Cetesb). As showed high carcinogenic risk, otherwise Cu only represented risk to human health in the most restrictive scenario, when 100% of the vegetables consumed were taken from the contaminated area. There was difference in the As availability between natural soil and artificial soil (ArtS) which was composed by sand, Kaolinite and powdered coconut fiber. As availability was high in the ArtS and it decreased the collembola reproduction. The Lowest Observed Effect Concentration (LOEC) on SAT were 0.25 mg kg-1, while and the No Observed Effect Concentration (LOEC) were less than 0.25 mg kg-1. Otherwise, the LOEC were 8.41 mg kg-1 in the natural soil, but it was not possible to define the NOEC. Avaliação de risco a saúde humana Bacia hidrográfica Colêmbolo Elementos potencialmente tóxicos Heavy metals Human health risk assessment Metais pesados Potential toxics elements Springtails (Collembola) Teste toxicológico Toxicological tests Watershed
48	Teores de elementos potencialmente tóxicos em solos de uma bacia hidrográfica e avaliação de risco à saúde humana / Watershed soils contents of potentially toxics elements in soils from an watershed and human health risk assessment Evandro Barbosa da Silva 23 April 2013 (has links) A contaminação dos solos por elementos potencialmente tóxicos (EPTs) provoca alterações na estrutura e no funcionamento dos ecossistemas, além de oferecer riscos à saúde pública. Os EPTs estão presentes naturalmente no ambiente, sendo constituintes de rochas e sedimentos. Entretanto, atividades antropogênicas como emissões industriais, uso de efluentes urbanos, dejetos de animais, biossólidos, fertilizantes e defensivos agrícolas podem contribuir para aumento da concentração dos EPTs. O solo é um dos principais meios de exposição dos EPTs aos seres humanos. Logo, é importante quantificar os teores dos EPTs nos solos e sua distribuição na microbacia para poder avaliar o risco a saúde humana. Os efeitos dos elementos tóxicos que chegam ao solo sobre a diversidade e funcionalidade da biota podem ser avaliados por meio de testes ecotoxicológicos. Alguns organismos são bons indicadores ambientais por participarem de processos biológicos importantes do solo. Os principais organismos utilizados são os colêmbolos, artrópodes terrestres com alta diversidade e abundância, sendo encontrado em todos os biomas. Nesse estudo, quantificaram-se os teores de Arsênio (As), Cádmio (Cd), Cobalto (Co), Cobre (Cu), Cromo (Cr), Chumbo (Pb), Níquel (Ni) e Zinco (Zn) em amostras de 15 solos da microbacia do Rio Guamium, localizada em Piracicaba, São Paulo. Foi realizado experimento em casa de vegetação com alface (Lactuca sativa L.), pepino (Cucumis sativus L.), beterraba (Beta vulgaris L.) e rúcula (Eruca sativus Mill.) para avaliar o risco a saúde humana. Foi avaliado também o efeito da aplicação de doses de As na reprodução dos colêmbolos. Para tanto, foram coletadas amostras de solos nas profundidades 0 - 0,1; 0,1 - 0,2; 0,2 - 0,3; 0,3 - 0,4; 0,4 - 0,6; 0,6 - 0,9 e 0,9 - 1,2 m. Foi realizada a extração dos EPTs pelo método EPA 3051a (0,5 g de solo + 9 ml HNO3 + 3 ml HCl com digestão assistida por forno microondas). Os EPTs que apresentaram as maiores concentrações foram o As (3 pontos) e Cu (1 ponto), sendo as concentrações superiores ou iguais ao valor de prevenção estabelecido pelo órgão ambiental paulista (Cetesb). O As apresentou elevado risco carcinogênico, enquanto o Cu apresentou risco à saúde humana apenas quando 100 % dos vegetais consumidos eram provenientes da área com elevado teor de Cu, sendo este o cenário mais restritivo. Houve diferença na disponibilidade de As entre o solo natural e o solo artificial tropical (SAT), composto por areia, caulinita e pó de fibra de coco. O SAT apresentou alta disponibilidade de As o que reduziu a taxa de reprodução dos colêmbolos. No SAT a LOEC (Lowest Observed Effect Concentration) foi 0,25 mg kg-1 e a NOEC (No Observed Effect Concentration) < 0,25 mg kg-1. No solo natural não foi possível determinar a NOEC, enquanto a LOEC foi 8,41 mg kg-1. / Soil contamination by potential toxics elements (PTEs) can change the ecosystem structure, its function and can cause risk to human health. PTEs occur naturally in the environment; however human activities such as industrial emissions, urban sewage, animal waste, biosolids, fertilizers and pesticides can increase their concentration. Soil is one of the main pathways to human exposure, so it is important to evaluate the contents of PTEs in soils and their distribution in the watershed in order to assess the human health risk. The effects of PTEs that reach the soil on the diversity and functionality of microorganisms can be evaluated by ecotoxicological tests. Organisms that take part of the biological process can be used as environment quality indicators. One of them is the springtails (Collembola) that are wide spread and have high diversity, being found in all ecosystems. In this study, we evaluated the Arsenic (As), Cadmium (Cd), Cobalt (Co), Copper (Cu), Chromium (Cr), Lead (Pb), Nickel (Ni) and Zinc (Zn) contents in 15 soil from Guamium watershed, located in Piracicaba, state of Sao Paulo, Brazil. To assess the human health risk lettuce (Lactuca sativa L.), cucumber (Cucumis sativus L.), sugar beet (Beta vulgaris L.) and rocket (Eruca sativus Mill.) were cultivated under greenhouse conditions. The effect of As rates on collembola reproduction was also evaluated. Soil samples were collected in the following depths: 0 - 0.1; 0.1 - 0.2; 0.2 - 0.3; 0.3 - 0.4; 0.4 - 0.6; 0.6 - 0.9 e 0.9 - 1.2 m. Contents of PTEs were obtained after microwave extraction by EPA 3051a method (0.5 g soil + 9 mL HNO3 + 3 mL HCl). As and Cu had the highest contents, and their concentration were close or higher than prevention value established by Sao Paulo state environmental agency (Cetesb). As showed high carcinogenic risk, otherwise Cu only represented risk to human health in the most restrictive scenario, when 100% of the vegetables consumed were taken from the contaminated area. There was difference in the As availability between natural soil and artificial soil (ArtS) which was composed by sand, Kaolinite and powdered coconut fiber. As availability was high in the ArtS and it decreased the collembola reproduction. The Lowest Observed Effect Concentration (LOEC) on SAT were 0.25 mg kg-1, while and the No Observed Effect Concentration (LOEC) were less than 0.25 mg kg-1. Otherwise, the LOEC were 8.41 mg kg-1 in the natural soil, but it was not possible to define the NOEC. Avaliação de risco a saúde humana Bacia hidrográfica Colêmbolo Elementos potencialmente tóxicos Metais pesados Teste toxicológico Heavy metals Human health risk assessment Potential toxics elements Springtails (Collembola) Toxicological tests Watershed
49	Soil animal food webs in temperate forests: effects of forest management on trophic structure as indicated by molecular gut content, stable isotope and fatty acid analyses Ferlian, Olga 20 June 2014 (has links) No description available. 333 577 Predator-prey interactions Beech forests Soil arthropods Soil food web Centipedes Collembola Earthworms Fatty acid analysis Ökologie {Biologie} (PPN619463619)
50	Wirkungen von Biokohlen im System Boden-Pflanze Reibe, Katharina 06 July 2015 (has links) Die Anwendung von Biokohlen in der Landwirtschaft gewinnt durch die positiven Aspekte der Kohlenstoffsequestrierung, Bodenverbesserung und eines erhöhten Pflanzenwachstums in den letzten Jahren an Bedeutung. Deshalb geht die vorliegende Arbeit den Fragen nach, welche Wirkungen unterschiedliche Biokohlen in Kombination mit oder ohne Gärrest und / oder Stickstoffdünger auf die Bodenchemie, Bodenbiologie und Wachstum, Entwicklung, Ertrag, Ertragsstruktur, Nährstoffe sowie Qualität von Nutzpflanzen haben. Außerdem wurden die Effekte unterschiedlicher Biokohlen auf die Wurzelmorphologie von Sommerweizen quantifiziert. Eine weitere Frage war, inwiefern Biokohlen Stickstoffquellen sorbieren. Es wurden ein Feldversuch und mehrere Gefäßversuche durchgeführt, um die Änderungen der Bodenchemie, den Einfluss auf die Bodenbiologie am Beispiel von Collembolen und die Pflanzenparameter zu bestimmen. Für die Wurzeluntersuchungen wurden Rhizoboxversuche durchgeführt und zur Quantifizierung der Stickstoffsorption ein in vitro Versuch angelegt. Die Ergebnisse der Feld- und Gefäßuntersuchungen zeigten, dass die Biokohlen die Bodeneigenschaften positiv beeinflussten. Die Biokohlen nahmen keinen konsistenten Einfluss auf die Erträge von Kulturpflanzen. Die Nährstoffgehalte der Kulturpflanzen konnten zum Teil positiv beeinflusst werden. Die Collembolenabundanzen zeigten sowohl in der Feldstudie als auch im Gefäßversuch keine signifikanten Unterschiede zwischen den getesteten Biokohlen. Hohe Mengen der fermentierten HTC-Biokohle führten zu negativen Wirkungen auf die Collembolenabundanz im Gefäßversuch. Die Rhizoboxversuche zeigten einen positiven Einfluss der Pyro-Biokohle auf die oberirdische und unterirdische Trockenmasse sowie die Wurzelmorphologie von Sommerweizen. Unterschiedliche Stickstoffquellen wurden von der HTC-Biokohle stärker sorbiert als von der Pyro-Biokohle. Generell lässt sich aus den differenzierten Wirkungen der Biokohlen weitere Forschung mit dem Fokus Boden ableiten. / Over the past few years the use of biochars in agriculture has gained more importance due to positive effects on carbon sequestration, soil improvement and increased plant growth. Therefore, the present work pursues the question which effects different biochars have in combination with or without digestate and / or nitrogen fertilizer on soil chemistry, soil biology and growth, development, yield, yield components, nutrients and quality of crops. In addition, the effects of different biochars on root morphology of spring wheat were quantified. Further to elucidate potential mechanisms underlying biochar effects on crops it was studied how biochars sorb various nitrogen sources. A field test and several pot experiments were conducted to determine the changes in soil chemistry, the impact on soil-dwelling Collembola and plant parameters. For the root studies rhizobox experiments were performed. To quantify the nitrogen sorption of biochars an in vitro experiment was conducted. The results of the field test and pot experiments showed that biochars positively affected soil chemical characteristics. However, yields of crops were not consistently affected by biochars. The nutrient content of crops were positively influenced to some extent. The abundance of Collembola was not significantly influenced by the biochars tested in the field study and in the pot experiment. High amounts of fermented HTC-biochar had negative effects on the abundance of Collembola in the pot experiment. Rhizobox experiments showed a positive influence of Pyro-biochar on the aboveground dry matter, belowground dry matter and root morphology (e.g. root length) of spring wheat. Amount and reversibility of nitrogen sorption was dependent on the type of biochar with HTC-biochar sorbing more nitrogen than Pyro- biochar. Generally it can be concluded that because of the different effects of biochars further research with a focus on soil is needed. Bodenbiologie Stickstoffdüngung Bodenchemie Biokohle Pyrolyse Hydrothermale Carbonisierung Fermentierung Rhizobox Wurzelmorphologie Stickstoffsorption Collembolen fermentation nitrogen fertilization soil biology soil chemistry biochar pyrolysis hydrothermal carbonization rhizobox root morphology nitrogen sorption collembola 39 Landwirtschaft, Garten AR 18600 ZC 14000 ZC 15800

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