国际农业科学数据导航库-农业学术服务平台

Data from: Integrating remotely sensed fires for predicting deforestation for REDD+

负责人：

关键词：: Bayesian modeling;tropical forests;fire;Holocene;deforestation

DOI：: doi:10.5061/dryad.1925k

摘要：: nitoring data derived from the Moderate Resolution Imaging Spectroradiometer (MODIS). The literature review revealed fire remains to be incorporated as a key component

Data from: The oceanic biological pump: rapid carbon transfer to depth at continental margins during winter

负责人：

关键词：: MODIS ocean colour satellite data;Internet operated vehicle;Ocean Networks Canada;POC flux;NE Pacific;NEPTUNE cable observatory;Barkley Submarine Canyon;present day observations;winter phytoplankton blooms;2010\/2011

DOI：: doi:10.5061/dryad.59t11

摘要：: of surface chlorophyll-a concentrations from the NASA’s MODIS satellite in combination with hourly to daily observations from sea surface buoys and from

Data from: Caribou, water, and ice – fine-scale movements of a migratory arctic ungulate in the context of climate change

负责人：: Mathieu Leblond

关键词：: Behaviour Climate Global change Long-distance migration Migratory caribou Movements Phenology Scales Space use Step selection function

DOI：: doi:10.5061/dryad.4k275

摘要：: the Rivière-aux-Feuilles herd in northern Québec (Canada) with GPS telemetry collars and studied their space use. We measured contemporary (digital MODIS

Time Series of expected Nebraska Sandhills livestock forage (2000 - 2016)

负责人：

关键词：: Land Use Change, Remote Sensing

DOI：: doi:10.5066/p9boio3d

摘要：: s of non-climatic influences removed. Moderate Resolution Imaging Spectroradiometer (MODIS)-based Normalized Difference Vegetation Index (NDVI) data were use

Data from: Computational research on mobile pastoralism using agent-based modeling and satellite imagery

负责人：

关键词：: satellite image analysis;Agent-Based Modeling;Pastoralism;MODIS

DOI：: doi:10.5061/dryad.s4h26

摘要：: w computational approach for studying mobile pastoralism that overcomes these issues. Combining multi-temporal satellite images and agent-based modeling allows

Data from: Predicting bird phenology from space: satellite-derived vegetation green-up signal uncovers spatial variation in phenological synchrony

负责人：

关键词：: MODIS blue tit environmental heterogeneity EVI great tit mismatch reproductive phenology satellite derived spatial scale wild population

DOI：: doi:10.5061/dryad.7v1qg

摘要：: Population-level studies of how tit species (Parus spp.) track the changing phenology of their caterpillar food source have provided a mod

Data from: Leaf development and demography explain photosynthetic seasonality in Amazon evergreen forests

负责人：

关键词：: Proximal Remote Sensing;climate;Leaf Quality;Photosynthetic Capacity;Manaus K34 Site;phenology;MODIS EVI;RJA;Leaf Quantity;CAX

DOI：: doi:10.5061/dryad.8fb47

摘要：: in Earth system models. Combining camera observations with ecosystem carbon dioxide fluxes at forests across rainfall gradients in Amaz?nia, we show that aggregate canopy

Data from: The many faces of synapsid cranial allometry

负责人：

关键词：: Idelesaurus tataricus;\Tetracynodon\ darti;Patranomodon nyaphulii;Scalopodon tenuisfrons;Thrinaxodon liorhinus;Geikia locusticeps;Edaphosaurus cruciger;Lycideops longiceps;Gordonia traquairi;Abdalodon sp;Chiniquodon theotonicus;Eosimops newtoni;Eothyris parkeyi;Dicynodontoides nowacki;Dimetrodon limbatus;Viatkogorgon ivakhnenkoi;Peramodon amalitzkii;Alopecognathus angusticeps;Therocephalia;Vivaxosaurus trautscholdi;Dimetrodon grandis;Procynosuchus delaharpeae;Estemmenosuchus mirabilis;Tapinocaninus pamelae;Brachyprosopus broomi;Australosyodon nyaphuli;Lystrosaurus hedini;Tropidostoma dubium;Andescynodon mendozensis;Dolichuranus primaevus;Lumkuia fuzzi;Jonkeria truculenta;Dinodontosaurus pedroanum;Sycosaurus laticeps;Titanophoneus potens;Rhachiocephalus behemoth;Galeops whaitsi;Daqingshanodon limbus;Parakannemeyeria youngi;Cynosaurus suppostus;Mirotenthes digitipes;Vinceria andina;Arctops willistoni;Basilodon woodwardi;Charassognathus gracilis;Exaeretodon argentinus;Dinanomodon gilli;Inostrancevia alexandri;Eodicynodon oosthuizeni;Probelesodon lewisi;Rhachiocephalus magnus;Suminia getmanovi;Moschops capensis;Dvinia prima;Titanophoneus adamanteus;Varanosaurus acutirostris;Hofmeyria atavus;Hipposaurus boonstrai;Jimusaria sinkiangensis;Parakannemeyeria shenmuensis;Arctognathus curvimola;Syodon biarmicum;Angonisaurus cruickshanki;Exaeretodon riograndensis;Keyseria benjamini;Anteosaurus magnificus;Dinogorgon rubidgei;Cotylorhynchus romeri;Dinocephalia;Lystrosaurus murrayi;Endothiodon bathystoma;Olivierosuchus parringtoni;Probainognathus jenseni;Tritylodon longaevus;Ericiolacerta parva;Cyonosaurus longiceps;Stahleckeria potens;Struthiocephaloides duplessisi;Aerosaurus wellesi;Gorgonops torvus;Lycaenops ornatus;Ruhuhucerberus haughtoni;Sinognathus gracilis;Ophiacodon retroversus;Rhadiodromus mariae;Mycterosaurus longiceps;Elph borealis;Euchambersia mirabilis;Lycosuchus vanderrieti;Synapsida;Moschorhinus kitchingi;Clelandina rubidgei;Ictidosuchops rubidgei;Proburnetia viatkensis;Ctenospondylus;Odontocyclops whaitsi;Chaliminia musteloides;Cryptocynodon simus;Biarmosaurus tener;Scylacosaurus sclateri;Theriognathus microps;Shansiodon wuhsiangensis;Massetognathus pascuali;Mormosaurus seeleyi;Viatkosuchus sumini;Trirachodon berryi;Regisaurus jacobi;Platycraniellus elegans;Aleodon cf cromptoni;Aelurognathus tigriceps;Scaloporhinus angulorugatus;Sphenacodon ferox;Riograndia guaibensis;Casea brolii;Bauria cynops;Aulacephalodon bainii;Akidnognathus parvus;Glanosuchus macrops;Eriphostoma microdon;Pachygenelus monus;Emydops;Pachydectes elsi;Cynodontia;Moschowhaitsia vjuschkovi;Bulbasaurus phylloxyron;Ulemosaurus svijagensis;Rubidgea atrox;Dicynodon lacerticeps;Diademodon tetragonus;Cranial Allometry;Pascualgnathus polanskii;Lycaenops pricei;Diictodon feliceps;Lystrosaurus declivis;Mupashi migrator;Langbergia modisei;Annatherapsidus petri;Aleodon brachyrhamphus;Tapinocephalus atherstonei;Secodontosaurus obtusidens;Xiyukannemeyeria brevirostris;Ictidorhinus martinsi;Emydorhinus sciuroides;Ophiacodon sp;Australobarbarus kotelnitschi;Jachaleria candelariensis;Carboniferous;pelycosaurs;Sinophoneus yumenensis;Kawingasaurus fossilis;Galesaurus planiceps;Ictidosuchoides longiceps;Cistecephalus microrhinus;Compsodon helmoedi;Moschops koupensis;Leontosaurus vanderhorsti;Lycaenops n. sp.;Permian;Tetragonias njalilus;Microgomphodon oligocynus;Pristerognathus;Digalodon rubidgei;Kannemeyeria simocephalus;Lemurosaurus pricei;Oudenodon bainii;Herpetoskylax hopsoni;Triassic;Delectosaurus arefjevi;Daptocephalus leoniceps;Silphoictidoides ruhuhuensis;Bienotheroides wansienensis;Protheriodon estudianti;Smilesaurus ferox;Heleosaurus scholtzi;Robertia broomiana;Progalesaurus lootsbergensis;Rhinodicynodon gracile;Ophiacodon mirus;Struthiocephalus whaitsi;Scalaoposaurus constrictus;Prosictodon dubei;Ischigualastia jenseni;Paraburnetia sneeubergensis;Otsheria netzvetajevi;Eodicynodon oelofseni;Dimetrodon loomisi;Sycosaurus nowaki;Lystrosaurus curvatus;Cistecephaloides boonstrai;Allometry;Lycaenops angusticeps;Sinokannemeyeria sunchuanheensis;Kayentatherium wellesi;Varanops brevirostris;Ulemica efremovi;Cynognathus crateronotus;Proalopecopsis haughtoni;Ennatosaurus tecton;Gorgonopsia;Glaucosaurus megalops;Rechnisaurus cristarhynchus;Biarmosuchia;Euptychognathus bathyrhynchus;Burnetia mirabilis;Sintocephalus alticeps;Pristerodon mackayi

DOI：: doi:10.5061/dryad.56qq231

摘要：: than within non-mammalian synapsids. Further investigation using an ontogenetic series of the anomodont Diictodon feliceps shows that the pattern

Data from: The role of cryptic diversity and its environmental correlates in global conservation status assessments: Insights from the threatened

负责人：

关键词：: CHELSA;IUCN;high-throughput genomic data;Primula farinosa;land cover;MODIS

DOI：: doi:10.5061/dryad.62np6jd

摘要：: ng lineages. Additionally, we tested for isolation by distance among populations and applied linear and polynomial regressions to identify lineage-environment

Data from: A migratory northern ungulate in the pursuit of spring: jumping or surfing the green wave?

负责人：

关键词：: ungulate;plant phenology;Cervus elaphus;green wave;Migration;red deer;NDVI;Holocene

DOI：: doi:10.5061/dryad.3hr2c

摘要：: plant phenology (MODIS-NDVI) and space use of 167 migratory and 78 resident red deer (Cervus elaphus) using a space-time-time matrix of "springness", defined

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Data from: Integrating remotely sensed fires for predicting deforestation for REDD+

Data from: The oceanic biological pump: rapid carbon transfer to depth at continental margins during winter

Data from: Caribou, water, and ice – fine-scale movements of a migratory arctic ungulate in the context of climate change

Time Series of expected Nebraska Sandhills livestock forage (2000 - 2016)

Data from: Computational research on mobile pastoralism using agent-based modeling and satellite imagery

Data from: Predicting bird phenology from space: satellite-derived vegetation green-up signal uncovers spatial variation in phenological synchrony

Data from: Leaf development and demography explain photosynthetic seasonality in Amazon evergreen forests

Data from: The many faces of synapsid cranial allometry

Data from: The role of cryptic diversity and its environmental correlates in global conservation status assessments: Insights from the threatened

Data from: A migratory northern ungulate in the pursuit of spring: jumping or surfing the green wave?

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