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Planting trees in the agricultural landscape, in the form of establishing agroforestry systems, has a significant role to play in potentially improving ecosystem services, such as increased biodiversity, reduced soil erosion, increased soil carbon storage, improved food security and nutrition, and reduced greenhouse gas emissions. While the role of trees in agroforestry systems in improving ecosystem services has been researched, studies in new systems/regions and new agroforestry system designs are still emerging. This Special Issue includes selected papers presented at the 4th World Congress on Agroforestry, Montpellier, France 20–22 May 2019, and other volunteer papers. The scope of articles includes all aspects of agroforestry systems.
farmers’ knowledge --- ahannon-wiener index --- economic benefits --- alley cropping --- lignin --- shelterbelts --- agroforestry --- natural capital --- forest farming --- nutrient content --- agroforestry system --- review --- Amazonia --- cropland --- riparian buffers --- climate change --- subtropical acidic forest soil --- bees --- phosphorus --- pollination --- 15N tracing experiment --- stable isotope --- West Java --- interspecific competition --- growth form --- cropping system --- climate change mitigation --- gross N transformation rates --- East Africa --- improved-fallow --- N-fixing trees --- carbon sequestration --- home garden --- margalef index --- windbreaks --- leaf nutrient diagnosis --- agroforestry systems --- pollinators --- sorption --- forestland --- China --- temperature change --- fractionation --- hedgerows --- native trees --- slash-and-mulch --- soil N --- shade tree species --- soil C --- Alpinia oxyphylla --- sustainable management --- plant water use --- rubber-based agroforestry system --- ecosystem services --- Indonesia
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The anthropogenic loading of phosphorus (P) to water bodies continues to increase worldwide, in many cases leading to increased eutrophication and harmful algal blooms. Determining the sources of P and the biogeochemical processes responsible for this increase is often difficult because of the complexity of the inputs and pathways, which vary both in spatial and temporal scales. In order to effectively develop strategies to improve water quality, it is essential to develop a comprehensive understanding of the relationship of P pools with biological uptake and cycling under varied soil and water conditions. In this ebook, eight chapters cover the various aspects of basic-applied research on mineral–P interaction and how these reactions impact P mobilization, bioavailability, transfer, and speciation of P in different soil matrices using advanced analytical methods. Some of these methods include the application of XANES and field-based research related to stream bank legacy nutrients; natural and anthropogenic eutrophication and its relationship to climate change; and the evaluation of the impact of P due to (i) grazing systems, (ii) weathering and vegetation, and iii) soil and manure management practices. In addition, two review chapters take a holistic approach to cover an expansive area of P transformation processes along the cropland–riparian–stream continuum and the assessment of legacy P. Together, these contributions improve our current understanding of the reactions and processes that impact P concentration, speciation, cycling, loss, and transfer from agroecosystems.
Research & information: general --- eutrophication --- phosphorus --- water quality --- sediment --- dissolved oxygen --- phosphorus mobilization --- climate change --- algae bloom --- legacy sediments --- equilibrium phosphorus concentration --- sorption --- desorption --- anoxic --- chemical P extraction --- microanalysis --- X-ray absorption near-edge structure (XANES) spectroscopy --- soil P --- vertical and horizontal P distribution --- runoff water --- exclusions --- strategic grazing --- dissolved reactive phosphorus --- total phosphorus --- soil test phosphorus --- soil stratification --- soil fertility --- phosphorus cycling --- weathering --- iron speciation --- biogeochemistry --- legacy phosphorus --- speciation --- transformation --- accessibility --- best management practices --- corn silage --- erosion --- nutrient management --- liquid manure --- surface runoff --- agriculture --- riparian buffers --- critical source areas --- overland flow --- hydropedology --- snowmelt --- streamflow --- tile drainage --- phosphorus kinetics --- Fe-Al-hydroxide mixtures --- histidine --- malic acid --- n/a
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The anthropogenic loading of phosphorus (P) to water bodies continues to increase worldwide, in many cases leading to increased eutrophication and harmful algal blooms. Determining the sources of P and the biogeochemical processes responsible for this increase is often difficult because of the complexity of the inputs and pathways, which vary both in spatial and temporal scales. In order to effectively develop strategies to improve water quality, it is essential to develop a comprehensive understanding of the relationship of P pools with biological uptake and cycling under varied soil and water conditions. In this ebook, eight chapters cover the various aspects of basic-applied research on mineral–P interaction and how these reactions impact P mobilization, bioavailability, transfer, and speciation of P in different soil matrices using advanced analytical methods. Some of these methods include the application of XANES and field-based research related to stream bank legacy nutrients; natural and anthropogenic eutrophication and its relationship to climate change; and the evaluation of the impact of P due to (i) grazing systems, (ii) weathering and vegetation, and iii) soil and manure management practices. In addition, two review chapters take a holistic approach to cover an expansive area of P transformation processes along the cropland–riparian–stream continuum and the assessment of legacy P. Together, these contributions improve our current understanding of the reactions and processes that impact P concentration, speciation, cycling, loss, and transfer from agroecosystems.
Research & information: general --- eutrophication --- phosphorus --- water quality --- sediment --- dissolved oxygen --- phosphorus mobilization --- climate change --- algae bloom --- legacy sediments --- equilibrium phosphorus concentration --- sorption --- desorption --- anoxic --- chemical P extraction --- microanalysis --- X-ray absorption near-edge structure (XANES) spectroscopy --- soil P --- vertical and horizontal P distribution --- runoff water --- exclusions --- strategic grazing --- dissolved reactive phosphorus --- total phosphorus --- soil test phosphorus --- soil stratification --- soil fertility --- phosphorus cycling --- weathering --- iron speciation --- biogeochemistry --- legacy phosphorus --- speciation --- transformation --- accessibility --- best management practices --- corn silage --- erosion --- nutrient management --- liquid manure --- surface runoff --- agriculture --- riparian buffers --- critical source areas --- overland flow --- hydropedology --- snowmelt --- streamflow --- tile drainage --- phosphorus kinetics --- Fe-Al-hydroxide mixtures --- histidine --- malic acid --- n/a
Choose an application
The anthropogenic loading of phosphorus (P) to water bodies continues to increase worldwide, in many cases leading to increased eutrophication and harmful algal blooms. Determining the sources of P and the biogeochemical processes responsible for this increase is often difficult because of the complexity of the inputs and pathways, which vary both in spatial and temporal scales. In order to effectively develop strategies to improve water quality, it is essential to develop a comprehensive understanding of the relationship of P pools with biological uptake and cycling under varied soil and water conditions. In this ebook, eight chapters cover the various aspects of basic-applied research on mineral–P interaction and how these reactions impact P mobilization, bioavailability, transfer, and speciation of P in different soil matrices using advanced analytical methods. Some of these methods include the application of XANES and field-based research related to stream bank legacy nutrients; natural and anthropogenic eutrophication and its relationship to climate change; and the evaluation of the impact of P due to (i) grazing systems, (ii) weathering and vegetation, and iii) soil and manure management practices. In addition, two review chapters take a holistic approach to cover an expansive area of P transformation processes along the cropland–riparian–stream continuum and the assessment of legacy P. Together, these contributions improve our current understanding of the reactions and processes that impact P concentration, speciation, cycling, loss, and transfer from agroecosystems.
eutrophication --- phosphorus --- water quality --- sediment --- dissolved oxygen --- phosphorus mobilization --- climate change --- algae bloom --- legacy sediments --- equilibrium phosphorus concentration --- sorption --- desorption --- anoxic --- chemical P extraction --- microanalysis --- X-ray absorption near-edge structure (XANES) spectroscopy --- soil P --- vertical and horizontal P distribution --- runoff water --- exclusions --- strategic grazing --- dissolved reactive phosphorus --- total phosphorus --- soil test phosphorus --- soil stratification --- soil fertility --- phosphorus cycling --- weathering --- iron speciation --- biogeochemistry --- legacy phosphorus --- speciation --- transformation --- accessibility --- best management practices --- corn silage --- erosion --- nutrient management --- liquid manure --- surface runoff --- agriculture --- riparian buffers --- critical source areas --- overland flow --- hydropedology --- snowmelt --- streamflow --- tile drainage --- phosphorus kinetics --- Fe-Al-hydroxide mixtures --- histidine --- malic acid --- n/a
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