Data from: Fossilization of melanosomes via sulfurization

负责人：

Maria McNamara

关键词：

melanosomes sulfurization taphonomy fossil frogs Libros GC-MS ToF-SIMS

DOI：

doi:10.5061/dryad.540q6

摘要：

), fourier transform infrared spectroscopy (FTIR) and time of flight secondary ion mass spectrometry (ToF-SIMS) to assess the mode of preservation of fossil microstructures, confirmed as melanosomes

Data from: Ion microprobe measured stable isotope evidence for ammonite habitat and life mode during early ontogeny

负责人：

Linzmeier, Benjamin

关键词：

SIMS stable isotope Ammonoidea

DOI：

doi:10.5061/dryad.pq70h50

摘要：

embryonic shells. To investigate possible environmental changes experienced by ammonite hatchlings, we used secondary ion mass spectrometry (SIMS) to analyze

STEP Processes - Non-planning Units

负责人：

Daly, Brenda;;South African Environmental Observation Network

关键词：

Biodiversity STEP WMS

DOI：

doi:10.15493/sarva.bgis.10000102

摘要：

to: Cowling, R.M., Lombard, A.T., Rouget, M., Kerley G.I.H., Wolf T., Sims-Castley, R., Knight, A., Vlok, J.H.J., Pierce, S.M., Boshoff, A.F. and Wilson

Data from: Impacts of species richness on productivity in a large-scale subtropical forest experiment

负责人：

关键词：

Celtis biondii;Loropetalum chinense;Diospyros japonica;Castanopsis sclerophylla;trees;Syzygium buxifolium;Cinnamomum camphora;Elaeocarpus chinensis;afforestation;experiment;Viburnum setigerum;Rhaphiolepis indica;Rhododendron simsii;Hydrangea chinensis;Ailanthus altissima;Elaeocarpus glabripetalus;Nyssa sinensis;Pinus massoniana;Elaeocarpus japonicus;Acer davidii;Castanopsis eyrei;additive partitioning;Itea chinensis;functional diversity;overyielding;Eurya muricata;Idesia polycarpa;Camellia chekiangoleosa;Quercus phillyreoides;Machilus leptophylla;Ardisia crenata;carbon sequestration;Distylium buxifolium;Cyclobalanopsis glauca;Quercus fabri;Schima superba;Quercus acutissima;Ficus erecta;Castanea henryi;Machilus thunbergii;extinction;phylogenetic diversity;subtropical forest;Phyllanthus glaucus;Sapindus saponaria;Triadica cochinchinensis;Castanopsis carlesii;Cunninghamia lanceolata;Daphniphyllum oldhamii;biodiversity;Meliosma flexuosa;Rhododendron ovatum;Triadica sebifera;Rhus chinensis;Alniphyllum fortunei;Gardenia jasminoides;Photinia hirsuta;Quercus serrata;Machilus grijsii;Distylium myricoides;Melia azedarach;Liquidambar formosana;Lithocarpus glaber;Cyclobalanopsis myrsinifolia;Manglietia fordiana;Phoebe bournei;Choerospondias axillaris;Castanopsis fargesii;Betula luminifera;Koelreuteria bipinnata

DOI：

doi:10.5061/dryad.t86145r

摘要：

e than 150,000 trees in plots with 1 to 16 species. Simulating multiple extinction scenarios, we found that richness strongly increased stand-level

STEP Processes - Planning Units

负责人：

Daly, Brenda;;South African Environmental Observation Network

关键词：

Biodiversity STEP Unit Layer WMS

DOI：

doi:10.15493/sarva.bgis.10000103

摘要：

rrently possible Supplemental Information: Cowling, R.M., Lombard, A.T., Rouget, M., Kerley G.I.H., Wolf T., Sims-Castley, R., Knight, A., Vlok

Data from: Experimental evidence that evolutionarily diverse assemblages result in higher productivity

负责人：

关键词：

Liatris cylindracea Michx.;Asteraceae); Liatris cylindracea (Michx.;biomass production;ecosystem function;Asclepiadaceae;Poaceae;Andropogon gerardii Vitman;Pycnanthemum tenuifolium Schrad.;Lamiaceae;biodiversity;phylogenetic diversity;Doellingeria umbellata (P. Mill.) Nees;Asteraceae); Oligoneuron album (Nutt. G. L. Nesom;Elymus trachycaulus (Link) Gould ex Shinners;Poaceae); Schizachyrium scoparium (Michx. Nash;Oligoneuron album (Nutt.) G. L. Nesom;Scrophulariaceae;Asteraceae); Rudbeckia hirta (L. Asteraceae); Solidago nemoralis (Aiton;Scrophulariaceae);Desmodium canadense (L.) DC.;Penstemon hirsutus (L.) Willd.;Monarda fistulosa L.;complementarity;Poaceae); E. trachycaulus (Link) Gould ex Shinners;Asteraceae); Desmodium canadense (L.;Lamiaceae); P. virginianum (L. T. Dur & B. D. Jacks. Ex B. L. Rob & Fernald;Solidago nemoralis Aiton;Fabaceae); Monarda fistulosa (L.;Lamiaceae); Penstemon digitalis (Nutt. Ex Sims;Poaceae); Asclepias tuberosa (L.;2010-2012;: Andropogon gerardii (Vitman;Scrophulariaceae); and P. hirsutus (L. Willd.;Fabaceae;Rudbeckia hirta L.;Elymus canadensis L.;Fabaceae); Lespedeza capitata (Michx.;Pycnanthemum virginianum (L.) T. Durand & B. D. Jacks. ex B. L. Rob & Fernald;Asclepiadaceae); Doellingeria umbellata (Mill. Nees;Lamiaceae); Pycnanthemum tenuifolium (Schrad.;Penstemon digitalis Nutt. Ex Sims;Asteraceae;Lespedeza capitata Michx.;Asclepias tuberosa L.;Poaceae); Elymus canadensis (L.;Schizachyrium scoparium (Michx.) Nash

DOI：

doi:10.5061/dryad.t80fp

摘要：

There is now ample experimental evidence that speciose assemblages are more productive and provide a greater amount of ecosystem services than depauperate ones. However, these experiments often conclude that there is a higher probability of including complementary species combinations in assemblages with more species, and lack a priori prediction about which species combinations maximize function. Here I report the results of the first experiment that manipulates the evolutionary relatedness of constituent plant species across a richness gradient. I show that assemblages with distantly related species contributed most to the higher biomass production in multispecies assemblages, through species complementarity. Species produced more biomass than predicted from their monocultures when they were in plots with distantly related species, and produced the amount of biomass predicted from monoculture when sown with close relatives. This suggests that, in the absence of any other information, combining distantly related species in restored or managed landscapes can serve to maximize biomass production and carbon sequestration, thus merging calls to conserve evolutionary history and maximize ecosystem function.