Closing yield gaps through nutrient and water management.
about
Agricultural innovation to protect the environmentVigorous Root Growth Is a Better Indicator of Early Nutrient Uptake than Root Hair Traits in Spring Wheat Grown under Low FertilityRoots Withstanding their Environment: Exploiting Root System Architecture Responses to Abiotic Stress to Improve Crop TolerancePrimary and Secondary Yield Losses Caused by Pests and Diseases: Assessment and Modeling in CoffeeClimate analogues suggest limited potential for intensification of production on current croplands under climate changeCELL5M: A geospatial database of agricultural indicators for Africa South of the SaharaUncertainty in soil data can outweigh climate impact signals in global crop yield simulationsRole of root microbiota in plant productivityA World at Risk: Aggregating Development Trends to Forecast Global Habitat ConversionConservation planning in agricultural landscapes: hotspots of conflict between agriculture and natureImproving farming practices reduces the carbon footprint of spring wheat productionConstraints and potentials of future irrigation water availability on agricultural production under climate changeClosing yield gaps: perils and possibilities for biodiversity conservationMatching roots to their environmentLong-term incorporation of manure with chemical fertilizers reduced total nitrogen loss in rain-fed cropping systemsManaging nitrogen for sustainable development.Sustaining food self-sufficiency of a nation: The case of Sri Lankan rice production and related water and fertilizer demands.Resilience and reactivity of global food security.Land grabbing: a preliminary quantification of economic impacts on rural livelihoods.Molecular and genetic control of plant thermomorphogenesis.Interactions between temperature and drought in global and regional crop yield variability during 1961-2014Can sub-Saharan Africa feed itself?Getting Road Expansion on the Right Track: A Framework for Smart Infrastructure Planning in the Mekong.Green and blue water demand from large-scale land acquisitions in Africa.Yield Gap, Indigenous Nutrient Supply and Nutrient Use Efficiency for Maize in China.Exploiting Co-Benefits of Increased Rice Production and Reduced Greenhouse Gas Emission through Optimized Crop and Soil Management.Plant-based assessment of inherent soil productivity and contributions to China's cereal crop yield increase since 1980.Root traits for infertile soilsOptimizing rice yields while minimizing yield-scaled global warming potential.Transportability of confined field trial data for environmental risk assessment of genetically engineered plants: a conceptual framework.Spatio-temporal dynamics of maize yield water constraints under climate change in Spain.Global potential of biospheric carbon management for climate mitigation.Decoupling of greenhouse gas emissions from global agricultural production: 1970-2050.Growing sensitivity of maize to water scarcity under climate change.Spatially explicit estimates of N2 O emissions from croplands suggest climate mitigation opportunities from improved fertilizer management.Random Forests for Global and Regional Crop Yield PredictionsLand management: data availability and process understanding for global change studies.Potential negative consequences of geoengineering on crop production: A study of Indian groundnutEstimating yield gaps at the cropping system level.Recent Genetic Gains in Nitrogen Use Efficiency in Oilseed Rape.
P2860
Q27010806-F62C93B7-49F2-44A3-86AF-17B6B6872705Q27306913-3F50236C-B908-44B5-AD96-88A2A0E143B4Q28070109-871108C6-E189-4B7C-95EC-625E317556DFQ28468453-D7BB9B11-03F2-48F6-BC04-1E500F478E8AQ28590151-20E3BF71-8FCC-432A-84B3-BF974A2EC439Q28595909-A980DEF2-2DA2-4389-95E1-6D149C3A4C04Q28597407-9450207D-570E-47B0-94DC-B81C4C01E701Q28597782-F5E58867-042A-4CB4-9F66-40E2958BB7D7Q28606677-67A2EB94-68A1-42BD-9EB4-221EB4B02D07Q28607345-5E3E7C5F-1A96-4019-98F3-2D2F00F0E723Q28651480-8E35061C-F728-4154-A3D7-7F504BEE6EF3Q28657977-6D5B44D4-8A77-4175-80EC-B2CF6CF63C70Q28658895-A856D1BF-685D-40D0-9FBB-E692A7EBD623Q28680741-BBBA0C4A-7ADF-4CA8-9E8E-7A658ABBAD5DQ28829528-0C08A282-23AF-443E-8DD8-7EBDB546A5B2Q30062104-7C2ED5D7-5A6E-4631-8683-DBE79055D310Q30278516-0B4D16FE-89A9-4009-A417-A163EB51ED36Q30299960-055D0BCC-C346-4826-990D-5B838E463AFBQ30301299-DF36BBB3-A50B-4965-A6D8-F6E4C2DFB1F4Q30314689-EA01DE93-6741-439B-BBA5-7C5FAAE4DC16Q30376295-2F4CBEA6-F7B4-4366-8DEF-BE88BF470F7DQ30379468-D4CBA18A-15BE-4D61-B597-3067E2A29A77Q30379742-E97097C5-2D49-4E71-B2C4-B743B740B57EQ30380802-F86E3C85-9F47-41B0-A353-0744F50C4549Q30387225-C68A7515-AB55-4262-96A4-CA41DE4CB555Q30387294-C6A9A3E9-2248-4F48-99B8-17DB5D0E8EDBQ30393110-369022F7-F036-44ED-A4C0-DFFC3EC77A3DQ30393639-62EB26F2-3AD2-4199-B58C-B62D89EE53FFQ30675855-2E7999E1-5F6A-43A5-B4EC-BB1EB9B2E2A7Q30801117-10F05856-4113-413D-8AA6-6F80BC182C4CQ30827782-2806BAA4-0FF5-4C2C-86E5-C2CE543B9D46Q30870513-D3D1C58E-18C8-48BE-9488-7F9EF217ED36Q31003856-69BBAB04-2233-4E1C-B322-E89508D790F3Q31039518-0E51DE32-EB3D-4189-AC80-6A049C9262ACQ31096545-546A6A93-5A36-4268-8533-4734ACAFD85BQ31105322-634C319D-1959-44E1-AD97-0D0D09635FF7Q31116809-91D44FB8-5441-4E02-955B-9FB162A00C03Q31161418-3F1E8085-BC08-4A71-B99C-06F3DC4F4E8AQ33646597-4A6B3392-B79A-4FCD-891A-11E3D8FDD12AQ33770440-DBC99D95-19EA-4451-99DF-F3A7A8F0A07A
P2860
Closing yield gaps through nutrient and water management.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
2012年论文
@zh
2012年论文
@zh-cn
name
Closing yield gaps through nutrient and water management.
@en
Closing yield gaps through nutrient and water management.
@nl
type
label
Closing yield gaps through nutrient and water management.
@en
Closing yield gaps through nutrient and water management.
@nl
prefLabel
Closing yield gaps through nutrient and water management.
@en
Closing yield gaps through nutrient and water management.
@nl
P50
P356
P1433
P1476
Closing yield gaps through nutrient and water management.
@en
P2888
P304
P356
10.1038/NATURE11420
P407
P577
2012-08-29T00:00:00Z
P5875
P6179
1014138923