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The articles in this Special Issue cover a very wide range of topics related to the cultivation, management and use of fast-growing tree species. In addition to research on breeding and on the influence of pruning practices on the height growth of paulownia, three articles deal with the influence of site characteristics and nutrient availability on the physiology and yield security of fast-growing tree species. Another article focuses on the modeling of soil carbon in Salix plantations, while the article by Boruszewski et al. reports on potentially suitable areas for the planting of fast-growing tree species in Poland. Zitzmann and Rode examine the impact of short-rotation plantation management on phytodiversity, while Helbig et al. deal with the influence of leaf feeding on the growth of poplars and willows. Finally, Hernandez-Estrada et al. describe the dry matter loss of poplar wood chips during storage.

Research & information: general --- Biology, life sciences --- Forestry & related industries --- woody biomass crops --- bioenergy --- biodiversity --- species richness --- flora --- vascular plants --- short rotation coppices --- poplars --- willows --- feeding simulation --- defoliation --- herbivory --- short rotation coppice --- phosphatase activity --- nutrient content --- growth stages --- biomass --- willow --- Salix --- capacity --- European larch --- fast-growing trees --- plantations --- plantation area --- poplar cultivar "Hybrid 275" --- sown area --- biomass production --- life cycle assessment --- climate impact --- soil organic carbon --- genotypic difference --- CRISPR/Cas9 --- genome editing --- Populus --- INRA 717-1B4 --- pyramidal plant habitus --- leaf petiole angle --- branch angle --- nitrogen --- phosphorus --- carbon --- physiology --- F. mandshurica --- Robinia pseudoacacia L. --- photosynthetic vitality --- chlorophyll and phenol content --- nutrition supply --- dry matter yield --- land reclamation --- spring pruning --- year-long pruning --- branching --- angle diversion of sprout --- dry matter losses --- poplar wood chips --- laboratory scale --- cultivable saproxylic microbiota --- woody biomass crops --- bioenergy --- biodiversity --- species richness --- flora --- vascular plants --- short rotation coppices --- poplars --- willows --- feeding simulation --- defoliation --- herbivory --- short rotation coppice --- phosphatase activity --- nutrient content --- growth stages --- biomass --- willow --- Salix --- capacity --- European larch --- fast-growing trees --- plantations --- plantation area --- poplar cultivar "Hybrid 275" --- sown area --- biomass production --- life cycle assessment --- climate impact --- soil organic carbon --- genotypic difference --- CRISPR/Cas9 --- genome editing --- Populus --- INRA 717-1B4 --- pyramidal plant habitus --- leaf petiole angle --- branch angle --- nitrogen --- phosphorus --- carbon --- physiology --- F. mandshurica --- Robinia pseudoacacia L. --- photosynthetic vitality --- chlorophyll and phenol content --- nutrition supply --- dry matter yield --- land reclamation --- spring pruning --- year-long pruning --- branching --- angle diversion of sprout --- dry matter losses --- poplar wood chips --- laboratory scale --- cultivable saproxylic microbiota

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• Reference Manager
• EndNote
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The articles in this Special Issue cover a very wide range of topics related to the cultivation, management and use of fast-growing tree species. In addition to research on breeding and on the influence of pruning practices on the height growth of paulownia, three articles deal with the influence of site characteristics and nutrient availability on the physiology and yield security of fast-growing tree species. Another article focuses on the modeling of soil carbon in Salix plantations, while the article by Boruszewski et al. reports on potentially suitable areas for the planting of fast-growing tree species in Poland. Zitzmann and Rode examine the impact of short-rotation plantation management on phytodiversity, while Helbig et al. deal with the influence of leaf feeding on the growth of poplars and willows. Finally, Hernandez-Estrada et al. describe the dry matter loss of poplar wood chips during storage.

Research & information: general --- Biology, life sciences --- Forestry & related industries --- woody biomass crops --- bioenergy --- biodiversity --- species richness --- flora --- vascular plants --- short rotation coppices --- poplars --- willows --- feeding simulation --- defoliation --- herbivory --- short rotation coppice --- phosphatase activity --- nutrient content --- growth stages --- biomass --- willow --- Salix --- capacity --- European larch --- fast-growing trees --- plantations --- plantation area --- poplar cultivar “Hybrid 275” --- sown area --- biomass production --- life cycle assessment --- climate impact --- soil organic carbon --- genotypic difference --- CRISPR/Cas9 --- genome editing --- Populus --- INRA 717-1B4 --- pyramidal plant habitus --- leaf petiole angle --- branch angle --- nitrogen --- phosphorus --- carbon --- physiology --- F. mandshurica --- Robinia pseudoacacia L. --- photosynthetic vitality --- chlorophyll and phenol content --- nutrition supply --- dry matter yield --- land reclamation --- spring pruning --- year-long pruning --- branching --- angle diversion of sprout --- dry matter losses --- poplar wood chips --- laboratory scale --- cultivable saproxylic microbiota --- n/a --- poplar cultivar "Hybrid 275"

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Energies is open to submissions for a Special Issue on “Renewable Energy Production from Energy Crops and Agricultural Residues”. Biomass represents an important source of renewable and sustainable energy production. Its increasing consumption is mainly related to the increase in global energy demand and fossil fuel prices, but also to a lower environmental impact compared to non-renewable fuels. These factors take RED II directives into consideration. In the past, forestry interventions were the main supply source of biomass, but in recent decades two others sources have entered the international scene. These are dedicated energy crops and agricultural residues, which are important sources of biomass for biofuel and bioenergy. Below, we consider four main value chains: • Oil crops: Oil production from non-food oilseed crops (such as camelina, Crambe, safflower, castor, cuphea, cardoon, etc.), oil extraction, and oil utilization for fuel production. • Lignocellulosic crops: Biomass production from perennial grasses (miscanthus, giant reed, switchgrass, reed canary grass, etc.), woody crops (willow, poplar, Robinia, eucalyptus, etc.), and agricultural residues (pruning, maize cob, maize stalks, wheat chaff, sugar cane straw, etc.), considering two main transformation systems: 1. Electricity/heat production 2. Second-generation ethanol production • Carbohydrate crops (cereals, sweet sorghum, sugar beets, sugar cane, etc.) for ethanol production. • Fermentable crops (maize, barley, triticale, Sudan grass, sorghum, etc.) and agricultural residues (chaff, maize stalks and cob, fruit and vegetable waste, etc.) for production of biogas and/or biomethane.

Research & information: general --- Technology: general issues --- bioenergy --- crop by-products --- harvesting methods --- maize cob --- wheat chaff --- combine harvesting --- olive groves --- pruning --- stationary chipper --- harvesting system --- hog fuel --- pruning supply chain --- populus --- biomass --- yield energy value --- lower heating value --- ash content --- sulphur --- circular bioeconomy --- oil crops --- agricultural residues --- thermophysical and chemical features --- wheat --- straw --- weed seed --- biocommodity --- threshing --- pruning harvesting --- biomass quality --- slope --- work productivity --- bioresource --- cereals --- commodity --- harvest index --- staple foods --- triticum --- Miscanthus x giganteus --- environmental impact --- agricultural production --- digestate --- eucalyptus --- woody biomass --- storage of fine wood chips --- moisture content --- calorific value --- dry matter loss --- Eucalyptus --- tree whole stem --- firewood logs --- storage system --- renewable energy --- harvesting --- suitable areas --- Central Italy --- Corine Land Cover --- short rotation coppice --- Salix --- genotype × site interaction --- nitrogen content --- sulphur content --- willow biomass --- soil organic carbon --- life cycle assessment --- spatial analysis --- greenhouse gas emissions --- energy return on investment --- lignocellulosic biomass --- hydrothermal pretreatment --- enzymatic hydrolysis --- sugar yield --- high-performance liquid chromatography (HPLC) analysis --- externalities --- economic analysis --- willow biomass production --- new varieties --- sustainable production --- renewable energy sources --- biofuels --- agriculture residues --- forecasting --- modelling --- Poland --- work performance --- harvesting loss --- fuelwood --- cable yarder --- CO2 emission --- pine plantations --- time study --- energy efficiency --- agroenvironmental mapping --- energy crop --- Jatropha curcas L. --- land suitability --- bio-based supply chains --- integrated biomass logistical center --- mixed integer programming model --- bioenergy --- crop by-products --- harvesting methods --- maize cob --- wheat chaff --- combine harvesting --- olive groves --- pruning --- stationary chipper --- harvesting system --- hog fuel --- pruning supply chain --- populus --- biomass --- yield energy value --- lower heating value --- ash content --- sulphur --- circular bioeconomy --- oil crops --- agricultural residues --- thermophysical and chemical features --- wheat --- straw --- weed seed --- biocommodity --- threshing --- pruning harvesting --- biomass quality --- slope --- work productivity --- bioresource --- cereals --- commodity --- harvest index --- staple foods --- triticum --- Miscanthus x giganteus --- environmental impact --- agricultural production --- digestate --- eucalyptus --- woody biomass --- storage of fine wood chips --- moisture content --- calorific value --- dry matter loss --- Eucalyptus --- tree whole stem --- firewood logs --- storage system --- renewable energy --- harvesting --- suitable areas --- Central Italy --- Corine Land Cover --- short rotation coppice --- Salix --- genotype × site interaction --- nitrogen content --- sulphur content --- willow biomass --- soil organic carbon --- life cycle assessment --- spatial analysis --- greenhouse gas emissions --- energy return on investment --- lignocellulosic biomass --- hydrothermal pretreatment --- enzymatic hydrolysis --- sugar yield --- high-performance liquid chromatography (HPLC) analysis --- externalities --- economic analysis --- willow biomass production --- new varieties --- sustainable production --- renewable energy sources --- biofuels --- agriculture residues --- forecasting --- modelling --- Poland --- work performance --- harvesting loss --- fuelwood --- cable yarder --- CO2 emission --- pine plantations --- time study --- energy efficiency --- agroenvironmental mapping --- energy crop --- Jatropha curcas L. --- land suitability --- bio-based supply chains --- integrated biomass logistical center --- mixed integer programming model

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Energies is open to submissions for a Special Issue on “Renewable Energy Production from Energy Crops and Agricultural Residues”. Biomass represents an important source of renewable and sustainable energy production. Its increasing consumption is mainly related to the increase in global energy demand and fossil fuel prices, but also to a lower environmental impact compared to non-renewable fuels. These factors take RED II directives into consideration. In the past, forestry interventions were the main supply source of biomass, but in recent decades two others sources have entered the international scene. These are dedicated energy crops and agricultural residues, which are important sources of biomass for biofuel and bioenergy. Below, we consider four main value chains: • Oil crops: Oil production from non-food oilseed crops (such as camelina, Crambe, safflower, castor, cuphea, cardoon, etc.), oil extraction, and oil utilization for fuel production. • Lignocellulosic crops: Biomass production from perennial grasses (miscanthus, giant reed, switchgrass, reed canary grass, etc.), woody crops (willow, poplar, Robinia, eucalyptus, etc.), and agricultural residues (pruning, maize cob, maize stalks, wheat chaff, sugar cane straw, etc.), considering two main transformation systems: 1. Electricity/heat production 2. Second-generation ethanol production • Carbohydrate crops (cereals, sweet sorghum, sugar beets, sugar cane, etc.) for ethanol production. • Fermentable crops (maize, barley, triticale, Sudan grass, sorghum, etc.) and agricultural residues (chaff, maize stalks and cob, fruit and vegetable waste, etc.) for production of biogas and/or biomethane.

Research & information: general --- Technology: general issues --- bioenergy --- crop by-products --- harvesting methods --- maize cob --- wheat chaff --- combine harvesting --- olive groves --- pruning --- stationary chipper --- harvesting system --- hog fuel --- pruning supply chain --- populus --- biomass --- yield energy value --- lower heating value --- ash content --- sulphur --- circular bioeconomy --- oil crops --- agricultural residues --- thermophysical and chemical features --- wheat --- straw --- weed seed --- biocommodity --- threshing --- pruning harvesting --- biomass quality --- slope --- work productivity --- bioresource --- cereals --- commodity --- harvest index --- staple foods --- triticum --- Miscanthus x giganteus --- environmental impact --- agricultural production --- digestate --- eucalyptus --- woody biomass --- storage of fine wood chips --- moisture content --- calorific value --- dry matter loss --- Eucalyptus --- tree whole stem --- firewood logs --- storage system --- renewable energy --- harvesting --- suitable areas --- Central Italy --- Corine Land Cover --- short rotation coppice --- Salix --- genotype × site interaction --- nitrogen content --- sulphur content --- willow biomass --- soil organic carbon --- life cycle assessment --- spatial analysis --- greenhouse gas emissions --- energy return on investment --- lignocellulosic biomass --- hydrothermal pretreatment --- enzymatic hydrolysis --- sugar yield --- high-performance liquid chromatography (HPLC) analysis --- externalities --- economic analysis --- willow biomass production --- new varieties --- sustainable production --- renewable energy sources --- biofuels --- agriculture residues --- forecasting --- modelling --- Poland --- work performance --- harvesting loss --- fuelwood --- cable yarder --- CO2 emission --- pine plantations --- time study --- energy efficiency --- agroenvironmental mapping --- energy crop --- Jatropha curcas L. --- land suitability --- bio-based supply chains --- integrated biomass logistical center --- mixed integer programming model

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Energies is open to submissions for a Special Issue on “Renewable Energy Production from Energy Crops and Agricultural Residues”. Biomass represents an important source of renewable and sustainable energy production. Its increasing consumption is mainly related to the increase in global energy demand and fossil fuel prices, but also to a lower environmental impact compared to non-renewable fuels. These factors take RED II directives into consideration. In the past, forestry interventions were the main supply source of biomass, but in recent decades two others sources have entered the international scene. These are dedicated energy crops and agricultural residues, which are important sources of biomass for biofuel and bioenergy. Below, we consider four main value chains: • Oil crops: Oil production from non-food oilseed crops (such as camelina, Crambe, safflower, castor, cuphea, cardoon, etc.), oil extraction, and oil utilization for fuel production. • Lignocellulosic crops: Biomass production from perennial grasses (miscanthus, giant reed, switchgrass, reed canary grass, etc.), woody crops (willow, poplar, Robinia, eucalyptus, etc.), and agricultural residues (pruning, maize cob, maize stalks, wheat chaff, sugar cane straw, etc.), considering two main transformation systems: 1. Electricity/heat production 2. Second-generation ethanol production • Carbohydrate crops (cereals, sweet sorghum, sugar beets, sugar cane, etc.) for ethanol production. • Fermentable crops (maize, barley, triticale, Sudan grass, sorghum, etc.) and agricultural residues (chaff, maize stalks and cob, fruit and vegetable waste, etc.) for production of biogas and/or biomethane.

bioenergy --- crop by-products --- harvesting methods --- maize cob --- wheat chaff --- combine harvesting --- olive groves --- pruning --- stationary chipper --- harvesting system --- hog fuel --- pruning supply chain --- populus --- biomass --- yield energy value --- lower heating value --- ash content --- sulphur --- circular bioeconomy --- oil crops --- agricultural residues --- thermophysical and chemical features --- wheat --- straw --- weed seed --- biocommodity --- threshing --- pruning harvesting --- biomass quality --- slope --- work productivity --- bioresource --- cereals --- commodity --- harvest index --- staple foods --- triticum --- Miscanthus x giganteus --- environmental impact --- agricultural production --- digestate --- eucalyptus --- woody biomass --- storage of fine wood chips --- moisture content --- calorific value --- dry matter loss --- Eucalyptus --- tree whole stem --- firewood logs --- storage system --- renewable energy --- harvesting --- suitable areas --- Central Italy --- Corine Land Cover --- short rotation coppice --- Salix --- genotype × site interaction --- nitrogen content --- sulphur content --- willow biomass --- soil organic carbon --- life cycle assessment --- spatial analysis --- greenhouse gas emissions --- energy return on investment --- lignocellulosic biomass --- hydrothermal pretreatment --- enzymatic hydrolysis --- sugar yield --- high-performance liquid chromatography (HPLC) analysis --- externalities --- economic analysis --- willow biomass production --- new varieties --- sustainable production --- renewable energy sources --- biofuels --- agriculture residues --- forecasting --- modelling --- Poland --- work performance --- harvesting loss --- fuelwood --- cable yarder --- CO2 emission --- pine plantations --- time study --- energy efficiency --- agroenvironmental mapping --- energy crop --- Jatropha curcas L. --- land suitability --- bio-based supply chains --- integrated biomass logistical center --- mixed integer programming model