Fertilidade e fauna edáfica em solo sob reflorestamento com paricá (Schizolobium amazonicum Huber ex Ducke) no município de Aurora do Pará

Com este estudo objetivou-se avaliar a variação na fertilidade do solo e na fauna edáfica sob reflorestamento com paricá (Schizolobium amazonicum Heber ex. Ducke) em monocultivo ou em sistema agroflorestal quando comparados com floresta secundária em área experimental considerando a sazonalidade da precipitação no período de 2009 e 2010. A área experimental pertence a Fazenda Tramontina Belém S/A, localizada no nordeste paraense, no município de Aurora do Pará. Foram analisados quatro tratamentos submetidos a reflorestamento com: Curauá (Ananas comosus var. erectifolius L.B.Smith), Paricá (Shizolobium var. amazonicum Huber ex Ducke) sob a forma de monocultivos, Paricá + curauá (Ananas comosus var. erectifolius L.B.Smith; Shizolobium var. amazonicum Huber ex Ducke); Paricá + Mogno + Freijó + Curauá (Shizolobium var. amazonicum Huber ex Ducke; Switenia macrophylla, King; Cordia goeldiana Huber; Ananas comosus var. erectifolius L.B.Smith). As amostragens foram realizadas em dezembro de 2009, abril e julho de 2010, o que caracterizou o período sazonal de transição (estiagem para chuva intensa), chuva intensa e estiagem respectivamente, para avaliar a granulometria, densidade aparente, densidade da partícula, porosidade total e umidade atual, bases trocáveis, soma de bases, CTC, acidez, fósforo, teor de carbono orgânico, pH, em três profundidades diferentes (0 – 10 cm. 10 - 20 cm; 20 – 40 cm) e a ocorrência de macrofauna edáfica. Os resultados mostraram a ação dos períodos sazonais sobre a densidade aparente, densidade da partícula, porosidade total do solo. Fatores químicos como, por exemplo, carbono orgânico, cujos teores variaram entre 5,85 g/kg e 13,00 g/kg, com teores elevados no sistema de cultivo S2, sofreu alterações nos períodos sazonais chuva intensa e estiagem. Quanto a fauna edáfica, foram capturados 9.964 invertebrados pertencentes a 26 táxons diferentes. Os mais abundantes foram Hymenoptera- Formicidae (5.805), Coleoptera (1.454), Acari (862), Collembola (649), Diplopoda (307) e Isopoda (110). Dos 26 táxons identificados, aproximadamente 40% deles apresentaram apenas um representante nas três amostragens efetuadas ou em apenas uma delas. Os maiores valores para frequência relativa ocorreu no sistema de cultivo S2, S4 e S3, respectivamente. O maior valor para frequência absoluta ocorreu durante o período sazonal chuva intensa em S1. As áreas sob reflorestamento com monocultivo e sistema agroflorestal paricà + curauá mostraram melhores desempenhos na recuperação da fertilidade do solo e da fauna edáfica comprovando a eficácia do paricá em monocultivo ou em sistema agroflorestal na recuperação da fertilidade do solo e da fauna edáfica.

Identificação de áreas preferenciais para uso de espécies florestais potenciais em sistemas agroflorestais no Arco Verde Paraense

O desmatamento é um processo evidente na Amazônia oriundo da ação antrópica predatória dos recursos naturais. A extração madeireira e a agropecuária são as principais atividades que tem promovido a destruição da floresta no Arco do desmatamento. Entretanto, o reflorestamento tem sido o foco de políticas públicas que o Governo tem desenvolvido por meio do Programa Arco Verde. No Pará este projeto está sendo aplicado em 16 municípios que integram as áreas críticas de desmatamento devido às pressões antrópicas exercidas. Nesse contexto, os sistemas agroflorestais tem sido uma das alternativas para reflorestamento dessas áreas. Neste trabalho objetivou-se a identificação de áreas preferenciais para plantio de 15 espécies florestais potenciais para uso em sistema agroflorestais. A partir do mapeamento da ocorrência das espécies florestais selecionadas, e do cruzamento de dados geográficos de tipologia climática e deficiência hídrica, identificou-se 24 zonas bioclimáticas no Arco Verde paraense. Os resultados para o plantio das espécies florestais em áreas preferenciais foram: J. copaia, T. serratifolia e B. excelsa são potenciais para serem plantadas em 100% do Arco Verde Paraense; C. pentandra, H. courbaril, S. morototoni e T. vulgaris são indicadas para serem plantadas em 98% da área alvo; C. odorata, C. goeldiana, D. odorata, S. macrophylla são indicadas para serem inseridas em 75% do Arco Verde paraense; C. guianensis, S. parahyba var. amazonicum, B. guianensis e V. maxima em 60% da área estudada. Em suma, é necessário se intensificar estudos em espécies florestais que são indicadas para as áreas preferenciais mais abrangentes.

Anatomia de órgãos foliares de Mapania Aubl. (Mapanioideae, Cyperaceae)

Estudou-se a anatomia dos órgãos foliares (folhas basais, ou catafilos, no caso de folhas ausentes, e brácteas involucrais) de três espécies de Mapania Aubl. Os espécimes de Mapania macrophylla (Boeck) H.Pfeiff. e M. pycnostachya (Benth.) T.Koyama, pertencentes à seção Pycnocephala, e M. sylvatica Aubl., pertencente à seção Mapania, foram coletados durante expedições científicas na Reserva Florestal Ducke em Manaus, AM, e constituem representantes de um mesmo gênero que ocupam três ambientes distintos da Floresta Amazônica. Em todos os órgãos, as espécies apresentam epiderme uniestratificada, com células de paredes delgadas, e estômatos paracíticos na face abaxial, no mesmo nível ou um pouco acima das demais células epidérmicas. O mesofilo é homogêneo e apresenta dois padrões distintos nos órgãos foliares: o primeiro com feixes vasculares em um único nível, sem extensão de bainha, idioblastos fenólicos abundantes e aerênquima não conspícuo; e o segundo padrão com feixes vasculares maiores e menores intercalados, com extensão de bainha do feixe e interrompidos por aerênquima conspícuo com células translúcidas. O primeiro padrão foi encontrado em brácteas involucrais de M. sylvatica e o segundo em todos os órgãos foliares das demais espécies. Essa diferença corrobora com as seções estabelecidas e é importante na diferenciação de espécies dentro do gênero. No pseudopecíolo de M. pycnostachya foi observada a presença de hipoderme, caráter importante na diferenciação de Mapania e Hypolytrum e que, portanto, necessita ser melhor estudado no gênero. Ainda, a presença de aerênquima, células epidérmicas com parede delgada e posição dos estômatos refletem a adaptação dessas espécies a ambientes úmidos de várzea e igapó onde são encontradas

Importance of anatomical leaf features for characterization of three species of Mapania (Mapanioideae, Cyperaceae) from the Amazon Forest, Brazil

Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)

Carbon stocks, tree diversity, and the role of organic certification in different cocoa production systems in Alto Beni, Bolivia

This study compares aboveground and belowground carbon stocks and tree diversity in different cocoa cultivation systems in Bolivia: monoculture, simple agroforestry, and successional agroforestry, as well as fallow as a control. Since diversified, agroforestry-based cultivation systems are often considered important for sustainable development, we also evaluated the links between carbon stocks and tree diversity, as well as the role of organic certification in transitioning from monoculture to agroforestry. Biomass, tree diversity, and soil physiochemical parameters were sampled in 15 plots measuring 48 × 48 m. Semi-structured interviews with 52 cocoa farmers were used to evaluate the role of organic certification and farmers’ organizations (e.g., cocoa cooperatives) in promoting tree diversity. Total carbon stocks in simple agroforestry systems (128.4 ± 20 Mg ha−1) were similar to those on fallow plots (125.2 ± 10 Mg ha−1). Successional agroforestry systems had the highest carbon stocks (143.7 ± 5.3 Mg ha−1). Monocultures stored significantly less carbon than all other systems (86.3 ± 4.0 Mg ha−1, posterior probability P(Diff > 0) of 0.000–0.006). Among shade tree species, Schizolobium amazonicum, Centrolobium ochroxylum, and Anadenanthera sp. accumulated the most biomass. High-value timber species (S. amazonicum, C. ochroxylum, Amburana cearensis, and Swietenia macrophylla) accounted for 22.0 % of shade tree biomass. The Shannon index and tree species richness were highest in successional agroforestry systems. Cocoa plots on certified organic farms displayed significantly higher tree species richness than plots on non-certified farms. Thus, expanding the coverage of organic farmers’ organizations may be an effective strategy for fostering transitions from monoculture to agroforestry systems.

Canopy cover mediates interactions between a specialist caterpillar and seedlings of a neotropical tree

1 Light availability may be crucial for understanding dynamics of plant–herbivore interactions in temperate and tropical forest communities. This is because local light availability can influence both tree seedling tolerance and susceptibility to herbivory – yet how they mediate levels of insect herbivory that vary with the density of host population is virtually unknown. Here we tested predictions of three key, non-mutually exclusive hypotheses of plant–herbivore interactions: the Limiting Resource Model (LRM), the Plant Vigour Hypothesis (PVH), and the Janzen-Connell Mechanism (JCM). 2 In an Amazonian forest, we planted Swietenia macrophylla seedlings (c. 5 months old) into natural canopy gaps and the shaded understorey and simulated the damage patterns of the specialist herbivore moth, Steniscadia poliophaea, by clipping seedling leaves. Over the next 8 months, we monitored seedling performance in terms of growth and survivorship and also quantified herbivory to new young leaves on a seasonal basis. 3 In support of the LRM, severe leaf damage (≥ 50%) was lethal for Swietenia macrophylla seedlings in the understorey, but in gaps only reduced seedling growth. In support of the PVH, gap seedlings suffered greater post-simulated herbivory (up to 100% defoliation) by S. poliophaea caterpillars than their understorey counterparts. 4 Adding a novel dimension to the Janzen–Connell hypothesis, we found that early wet season herbivory of seedlings in gaps increased with conspecific adult density within a 125-m radius; whereas in the understorey only those seedlings within 50 m of a Swietenia tree were attacked by caterpillars. 5 Synthesis. These results suggest lepidopterans that need young leaves for food may forage more widely in forests to find seedlings in light-rich canopy gaps. Moths may achieve this successfully by being first attracted to gaps, and then searching within them for suitable hosts. A conceptual model, integrating conspecific adult tree density with light-driven changes in seedling tolerance/vigour and their susceptibility to herbivory and mortality, is presented. Spatial variation in the light available to tree seedlings often affects their tolerance and vigour, which may have important consequences for leaf-chewing insects and the scale of density-dependent herbivory in forests.

Herbivores limit the population size of big-leaf mahogany trees in an Amazonian forest

The Janzen–Connell hypothesis proposes that specialized herbivores maintain high numbers of tree species in tropical forests by restricting adult recruitment so that host populations remain at low densities. We tested this prediction for the large timber tree species, Swietenia macrophylla, whose seeds and seedlings are preyed upon by small mammals and a host-specific moth caterpillar Steniscadia poliophaea, respectively. At a primary forest site, experimental seed additions to gaps – canopy-disturbed areas that enhance seedling growth into saplings – over three years revealed lower survival and seedling recruitment closer to conspecific trees and in higher basal area neighborhoods, as well as reduced subsequent seedling survival and height growth. When we included these Janzen–Connell effects in a spatially explicit individual-based population model, the caterpillar's impact was critical to limiting Swietenia's adult tree density, with a > 10-fold reduction estimated at 300 years. Our research demonstrates the crucial but oft-ignored linkage between Janzen–Connell effects on offspring and population-level consequences for a long-lived, potentially dominant tree species.

Contribution of woody habitat islands to the conservation of birds and their potential ecosystem services in an extensive Colombian rangeland

The conservation of birds and their habitats is essential to maintain well-functioning ecosystems including human-dominated habitats. In simplified or homogenized landscapes, patches of natural and semi-natural habitat are essential for the survival of plant and animal populations. We compared species composition and diversity of trees and birds between gallery forests, tree islands and hedges in a Colombian savanna landscape to assess how fragmented woody plant communities affect forest bird communities and how differences in habitat characteristics influenced bird species traits and their potential ecosystem function. Bird and tree diversity was higher in forests than in tree islands and hedges. Soil depth influenced woody species distribution, and canopy cover and tree height determined bird species distribution, resulting in plant and bird communities that mainly differed between forest and non-forest habitat. Bird and tree species and traits widely co-varied. Bird species in tree islands and hedges were on average smaller, less specialized to habitat and more tolerant to disturbance than in forest, but dietary differences did not emerge. Despite being less complex and diverse than forests, hedges and tree islands significantly contribute to the conservation of forest biodiversity in the savanna matrix. Forest fragments remain essential for the conservation of forest specialists, but hedges and tree islands facilitate spillover of more tolerant forest birds and their ecological functions such as seed dispersal from forest to the savanna matrix.

Vegetation, soil and site characteristics of samples taken along the Yamal Transet in 2007-2008

The overarching goal of the Yamal portion of the Greening of the Arctic project is to examine how the terrain and anthropogenic factors of reindeer herding and resource development combined with the climate variations on the Yamal Peninsula affect the spatial and temporal patterns of vegetation change and how these changes are in turn affecting traditional herding of the indigenous people of the region. The purpose of the expeditions was to collect groundobservations in support of remote sensing studies at four locations along a transect that traverses all the major bioclimate subzones of the Yamal Peninsula. This data report is a summary of information collected during the 2007 and 2008 expeditions. It includes all the information from the 2008 data report (Walker et al. 2008) plus new information collected at Kharasavey in Aug 2008. The locations included in this report are Nadym (northern taiga subzone), Laborovaya (southern tundra = subzone E of the Circumpolar Arctic Vegetation Map (CAVM), Vaskiny Dachi (southern typical tundra = subzone D), and Kharasavey (northern typical tundra = subzone C). Another expedition is planned for summer 2009 to the northernmost site at Belyy Ostrov (Arctic tundra = subzone B). Data are reported from 10 study sites - 2 at Nadym, 2 at Laborovaya, and 3 at Vaskiny Dachi and 3 at Kharasavey. The sites are representative of the zonal soils and vegetation, but also include variation related to substrate (clayey vs. sandy soils). Most of the information was collected along 5 transects at each sample site, 5 permanent vegetation study plots, and 1-2 soil pits at each site. The expedition also established soil and permafrost monitoring sites at each location. This data report includes: (1) background for the project, (2) general descriptions and photographs of each locality and sample site, (3) maps of the sites, study plots, and transects at each location, (4) summary of sampling methods used, (5) tabular summaries of the vegetation data (species lists, estimates of cover abundance for each species within vegetation plots, measured percent ground cover of species along transects, site factors for each study plot), (6) summaries of the Normalized Difference Vegetation Index (NDVI) and leaf area index (LAI) along each transect, (7) soil descriptions and photos of the soil pits at each study site, (8) summaries of thaw measurements along each transect, and (9) contact information for each of the participants. One of the primary objectives was to provide the Russian partners with full documentation of the methods so that Russian observers in future years could repeat the observations independently.