Mapping forest canopy height globally with spaceborne lidar
about
The effects of forest canopy shading and turbulence on boundary layer ozone.Vegetation Greening and Climate Change Promote Multidecadal Rises of Global Land Evapotranspiration.Spatial Configuration of Drought Disturbance and Forest Gap Creation across Environmental GradientsGlobal variations in ecosystem-scale isohydricity.Relationships between individual-tree mortality and water-balance variables indicate positive trends in water stress-induced tree mortality across North America.Forest structure drives global diversity of primates.An integrated pan-tropical biomass map using multiple reference datasets.Hypo-endemic onchocerciasis hotspots: defining areas of high risk through micro-mapping and environmental delineationDisentangling the Role of Climate, Topography and Vegetation in Species Richness Gradients.Defining functional biomes and monitoring their change globally.Global patterns and determinants of forest canopy height.Small Sample Sizes Yield Biased Allometric Equations in Temperate ForestsA high-resolution global flood hazard model.Observing terrestrial ecosystems and the carbon cycle from space.Global remote sensing of water-chlorophyll ratio in terrestrial plant leaves.Tropical protected areas reduced deforestation carbon emissions by one third from 2000-2012.Models meet data: Challenges and opportunities in implementing land management in Earth system models.Spatial relationships between above-ground biomass and bird species biodiversity in Palawan, Philippines.Vegetation demographics in Earth System Models: A review of progress and priorities.Leaf mass per area, not total leaf area, drives differences in above-ground biomass distribution among woody plant functional types.Water availability predicts forest canopy height at the global scale.Unexpectedly large impact of forest management and grazing on global vegetation biomass.Framing the concept of satellite remote sensing essential biodiversity variables: challenges and future directionsThe Fire Modeling Intercomparison Project (FireMIP), phase 1: experimental and analytical protocols with detailed model descriptionsImproving ecosystem productivity modeling through spatially explicit estimation of optimal light use efficiencyThreatened species impact assessments: survey effort requirements based on criteria for cumulative impactsAn Assessment of Methods and Remote-Sensing Derived Covariates for Regional Predictions of 1 km Daily Maximum Air TemperatureDifferential effects of environmental heterogeneity on global mammal species richnessBiomass turnover time in terrestrial ecosystems halved by land useClimate-biomes, pedo-biomes or pyro-biomes: which world view explains the tropical forest-savanna boundary in South America?Application of the metabolic scaling theory and water-energy balance equation to model large-scale patterns of maximum forest canopy heightMapping Forest Canopy Height over Continental China Using Multi-Source Remote Sensing DataAllometric Scaling and Resource Limitations Model of Tree Heights: Part 3. Model Optimization and Testing over Continental ChinaApplication of Physically-Based Slope Correction for Maximum Forest Canopy Height Estimation Using Waveform Lidar across Different Footprint Sizes and Locations: Tests on LVIS and GLASAllometric Scaling and Resource Limitations Model of Tree Heights: Part 1. Model Optimization and Testing over Continental USAAllometric Scaling and Resource Limitations Model of Tree Heights: Part 2. Site Based Testing of the ModelBiome-Scale Forest Properties in Amazonia Based on Field and Satellite ObservationsFiner resolution observation and monitoring of global land cover: first mapping results with Landsat TM and ETM+ dataThe role of trace gas flux networks in the biogeosciencesTwo-Dimensional Dam-Break Flood Analysis in Data-Scarce Regions: The Case Study of Chipembe Dam, Mozambique
P2860
Q30854402-3D8B90BB-7102-426A-AA7A-00DEB5528893Q31012913-1C290318-B9F6-4579-8C78-6A73C93994EAQ31106479-88A4D789-EF73-4498-85CF-A97EC5189EB6Q31110111-5420EE53-E8C1-431F-BEA6-C4DA5D59ECD8Q31130561-789E75C7-E06E-4AA6-A79E-FC8891388D13Q35158656-3CBF0669-C2B4-4460-82B2-0942B7A780B6Q35820687-B9A78D89-9938-4156-A7AB-92D9ED88346EQ35957156-F5193008-84A5-4381-BF31-D577A5CD2978Q35970228-3962E8BC-C735-4F2D-9CC7-B5E9FBE53C5EQ36024918-4BE2851D-0BFD-4F34-ADD5-3C6B140A6F11Q36212106-DF5B791D-74B6-4BCE-8A82-F6DE76360E4EQ36310510-D432C5AC-D654-48D3-9852-EED0CA8E6A0AQ37185502-6EED8A3F-B924-402B-87CB-4837C608AC77Q38282697-48F171F8-96DF-447E-B2E2-D823A5A99A10Q41358833-B5F88FEE-6520-4477-8CEE-D2D2D47208E0Q42630279-AF354BE4-60B4-4D3E-953E-7DD3E4AEBE52Q46242321-B52E77E9-9E05-460D-9CE3-DE58EE5DD118Q46247802-A7DDBFEF-9E05-460C-90C1-956751A4449AQ46305142-2046FFD5-7286-4CBE-9651-299CC7D2E416Q46540325-29ECF923-6F21-4FB9-8009-F74D74136208Q46661499-F3326112-9814-4BBC-9B88-B86E10FCAB74Q47572453-E4F69407-1565-4D8B-9E73-72C0DA35B5DDQ54988037-443F46B3-4F77-4AFB-90CB-8A612958B114Q56705572-8BA3E844-5007-4840-BCC1-C658C202574FQ56755145-72A711BD-532D-4AA5-9F89-60AB6A133C64Q56929663-2A8454B6-7EA8-4171-BAD7-520B9426A10AQ56937432-89622F19-272B-4732-90BB-93B607845E4EQ56961372-3729F5D9-9CBF-46BC-91EA-5916BAC77517Q57023000-67B1A1B0-2791-4D95-9609-7588E90955C6Q57054693-B7BBBC09-9D4A-4EEB-A3F6-1902F83F1735Q57159665-5ED7161A-C7F2-4ED5-80F4-37D64640DC8FQ57159713-96B1C22B-1E8E-4B5F-8C18-FD393EEC899BQ57159733-9C8DCB46-7A5D-4E82-A6CF-548C0A6ABA55Q57159738-34A663CB-292C-4B74-9CAF-42B558D77DE1Q57159778-9AB9F38B-DBB3-4A73-8930-EDBF5AA66980Q57159783-C8FA6ED2-CC39-4134-9E03-F31FAA2F2E1FQ57267675-7EAB56AD-2CFE-4733-980E-8369C1E1C17DQ57410715-9E2C38DE-C1F9-4AAB-8C51-28392C1EB9B0Q57492051-E5933813-6E0C-4ADB-B059-1F1CFAE9C515Q57527966-D839BF94-EB40-4211-A9AD-410462D3012E
P2860
Mapping forest canopy height globally with spaceborne lidar
description
im November 2011 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в листопаді 2011
@uk
name
Mapping forest canopy height globally with spaceborne lidar
@en
Mapping forest canopy height globally with spaceborne lidar
@nl
type
label
Mapping forest canopy height globally with spaceborne lidar
@en
Mapping forest canopy height globally with spaceborne lidar
@nl
prefLabel
Mapping forest canopy height globally with spaceborne lidar
@en
Mapping forest canopy height globally with spaceborne lidar
@nl
P2860
P356
P1476
Mapping forest canopy height globally with spaceborne lidar
@en
P2093
Alessandro Baccini
Naiara Pinto
P2860
P356
10.1029/2011JG001708
P407
P577
2011-11-19T00:00:00Z