Impacts of climate change and management responses in tropical forests depend on complex frugivore-mediated seed dispersal

AimBiodiversity outcomes under global change will be influenced by a range of ecological processes, and these processes are increasingly being considered in models of biodiversity change. However, the level of model complexity required to adequately account for important ecological processes often remains unclear. Here we assess how considering realistically complex frugivore-mediated seed dispersal influences the projected climate change outcomes for plant diversity in the Australian Wet Tropics (all 4313 species). LocationThe Australian Wet Tropics, Queensland, Australia. MethodsWe applied a metacommunity model (M-SET) to project biodiversity outcomes using seed dispersal models that varied in complexity, combined with alternative climate change scenarios and habitat restoration scenarios. ResultsWe found that the complexity of the dispersal model had a larger effect on projected biodiversity outcomes than did dramatically different climate change scenarios. Applying a simple dispersal model that ignored spatial, temporal and taxonomic variation due to frugivore-mediated seed dispersal underestimated the reduction in the area of occurrence of plant species under climate change and overestimated the loss of diversity in fragmented tropical forest remnants. The complexity of the dispersal model also changed the habitat restoration approach identified as the best for promoting persistence of biodiversity under climate change. Main conclusionsThe consideration of complex processes such as frugivore-mediated seed dispersal can make an important difference in how we understand and respond to the influence of climate change on biodiversity.

Vegetation structure and composition of tropical evergreen and deciduous forests in Uttara Kannada District, Western Ghats under different disturbance regimes

In the present paper, we present the structure and composition of tropical evergreen and deciduous forests in the Western Ghats monitored under a long-term programme involving Indian Institute of Science, Earthwatch and volunteer investigators from HSBC. Currently, there is limited evidence on the status and dynamics of tropical forests in the context of human disturbance and climate change. Observations made in this study show that the `more disturbed' evergreen and one of the deciduous plots have low species diversity compared to the less-disturbed forests. There are also variations in the size class structure in the more and `less disturbed' forests of all the locations. The variation is particularly noticeable in the DBH size class 10 - 15 cm category. When biomass stock estimates are considered, there was no significant difference between evergreen and deciduous forests. The difference in biomass stocks between `less disturbed' and `more disturbed' forests within a forest type is also low. Thus, the biomass and carbon stock has not been impacted despite the dependence of communities on the forests. Periodic and long-term monitoring of the status and dynamics of the forests is necessary in the context of potential increased human pressure and climate change. There is, therefore, a need to inform the communities of the impact of extraction and its effect on regeneration so as to motivate them to adopt what may be termed as ``adaptive resource management'', so as to sustain the flow of forest products.

Tailoring energy absorption capacity of CNT forests through application of electric field

This study examines the effect of electric field on energy absorption capacity of carbon nanotube forests (CNTFs), comprising of vertically aligned multiwalled carbon nanotubes, under both quasistatic (strain rate, (epsilon) over dot = 10(-3) s(-1)) and dynamic ((epsilon) over dot = similar to 10(3) s(-1)) loading conditions. Under quasistatic condition, the CNTFs were cyclically loaded and unloaded while electric field was applied along the length of carbon nanotube (CNT) either throughout the loading cycle or explicitly during either the loading or the unloading segment. The energy absorbed per cycle by CNTF increased monotonically with electric field when the field was applied only during the loading segment: A 7 fold increase in the energy absorption capacity was registered at an electric field of 1 kV/m whereas no significant change in it was noted for other schemes of electro-mechanical loading. The energy absorption capacity of CNTF under dynamic loading condition also increased monotonically with electric field; however, relative to the quasistatic condition, less pronounced effect was observed. This intriguing strain rate dependent effect of electric field on energy absorption capacity of CNTF is explained in terms of electric field induced strengthening of CNTF, originating from the time dependent electric field induced polarization of CNT. (C) 2015 Elsevier Ltd. All rights reserved.

Growth of ultrahigh density vertically aligned carbon nanotube forests for interconnects.

We present a general catalyst design to synthesize ultrahigh density, aligned forests of carbon nanotubes by cyclic deposition and annealing of catalyst thin films. This leads to nanotube forests with an area density of at least 10(13) cm(-2), over 1 order of magnitude higher than existing values, and close to the limit of a fully dense forest. The technique consists of cycles of ultrathin metal film deposition, annealing, and immobilization. These ultradense forests are needed to use carbon nanotubes as vias and interconnects in integrated circuits and thermal interface materials. Further density increase to 10(14) cm(-2) by reducing nanotube diameter is possible, and it is also applicable to nanowires.

The Rain Forests of Home: an Atlas of People and Place

pdf contains 31 pages

Downscaling of surface moisture flux and precipitation in the Ebro Valley (Spain) using analogues and analogues followed by random forests and multiple linear regression

In this paper, reanalysis fields from the ECMWF have been statistically downscaled to predict from large-scale atmospheric fields, surface moisture flux and daily precipitation at two observatories (Zaragoza and Tortosa, Ebro Valley, Spain) during the 1961-2001 period. Three types of downscaling models have been built: (i) analogues, (ii) analogues followed by random forests and (iii) analogues followed by multiple linear regression. The inputs consist of data (predictor fields) taken from the ERA-40 reanalysis. The predicted fields are precipitation and surface moisture flux as measured at the two observatories. With the aim to reduce the dimensionality of the problem, the ERA-40 fields have been decomposed using empirical orthogonal functions. Available daily data has been divided into two parts: a training period used to find a group of about 300 analogues to build the downscaling model (1961-1996) and a test period (19972001), where models' performance has been assessed using independent data. In the case of surface moisture flux, the models based on analogues followed by random forests do not clearly outperform those built on analogues plus multiple linear regression, while simple averages calculated from the nearest analogues found in the training period, yielded only slightly worse results. In the case of precipitation, the three types of model performed equally. These results suggest that most of the models' downscaling capabilities can be attributed to the analogues-calculation stage.

Competing Ecosystem services: an Assessment of Carbon and timber in the Tropical forests of Central America

4 p.

The Costs of Ecosystem Adaptation: Methodology and Estimates for Indian Forests

34 p.

Competing Ecosystem Services: an Assessment of Carbon and Timber in the Tropical Forests of Central America

29 p.

Diversidade, diferenciação e biogeografia de pequenos mamíferos não-voadores na Mata Atlântica ao norte do rio São Francisco Centro de Endemismo Pernambuco

As florestas tropicais brasileiras (Amazônia e a Mata Atlântica) possuem alta diversidade de espécies e atualmente estão separadas por um cinturão de vegetação aberta. Parte deste cinturão é ocupada pela Caatinga, onde se encontram os Brejos de Altitude, testemunhos das conexões históricas entre a Mata Atlântica e a Amazônia. O Centro de Endemismos Pernambuco (CEPE) é a unidade biogeográfica que compõe a Mata Atlântica ao norte do rio São Francisco e contém diversos táxons endêmicos. Esta região apresenta uma mastofauna compartilhada com a Amazônia, devido às conexões existentes durante o Cenozóico. A presença do rio São Francisco em seu limite sul pode atuar como barreira ao fluxo gênico e explicar os endemismos encontrados no CEPE. Contrastando com sua situação peculiar, a mastofauna do CEPE ainda carece de estudos aprofundados sobre a identificação de suas espécies, padrões geográficos e relações filogenéticas. Revisões recentes têm identificado espécies diferentes ao norte e ao sul do rio São Francisco, mas poucos trabalhos têm proposto hipóteses biogeográficas para o CEPE. Para ampliar o conhecimento sobre a identidade e distribuição geográfica dos pequenos mamíferos do CEPE e sua estrutura filogeográfica, foram realizados levantamentos de espécies e análises de diversidade genética e morfométrica para algumas espécies. Os levantamentos consistiram de visitas às coleções científicas a fim de identificar as espécies ocorrentes no CEPE e excursões de coleta com 5 a 17 noites consecutivas em 12 localidades ao longo do CEPE, que totalizaram 64691 armadilhas noites e resultaram na coleta de 476 exemplares de 31 espécies. As espécies foram identificadas com base na morfologia externa e craniana e por análises citogenéticas. Para investigar a biogeografia do CEPE, análises de genética de populações, filogeográficas e morfométricas foram realizadas para os marsupiais Caluromys philander, Didelphis aurita, Marmosa murina, Metachirus nudicaudatus e os roedores Akodon cursor, Oecomys catherinae e Rhipidomys mastacalis para avaliar a existência de diferenciação nas populações do CEPE e suas relações com as linhagens Amazônicas e Atlânticas. Estes resultados mostraram que a diversificação dos pequenos mamíferos do CEPE ocorreu tanto no Terciário quanto no Quaternário. Algumas populações, como em Caluromys philander e Oecomys catherinae, mostraram afinidades com linhagens amazônicas, enquanto outras, como em Metachirus nudicaudatus e Rhipidomys mastacalis, apresentaram afinidades com linhagens atlânticas. Os pequenos mamíferos do CEPE apresentaram diferenciação em relação às suas linhagens irmãs, com algumas linhagens podendo tratar-se de espécies ainda não descritas (e.g. Didelphis aff. aurita e Rhipidomys aff. mastacalis). Esta diferenciação provavelmente foi causada pelos eventos cíclicos de flutuações climáticas que provocaram elevações no nível do mar e retração das florestas tropicais, isolando as populações do CEPE. Por fim, para auxiliar na identificação das espécies em novas coletas, de suas distribuições geográficas e de suas características citogenéticas e ecológicas, foi elaborado um guia reunindo todas as informações disponíveis sobre as espécies de pequenos mamíferos do CEPE.