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Carbon Sequestration by Perennial Energy Crops: Is the Jury Still Out?Dry Matter Losses and Greenhouse Gas Emissions From Outside Storage of Short Rotation Coppice Willow ChipBreeding for Bio-ethanol Production in Lolium perenne L.: Association of Allelic Variation with High Water-Soluble Carbohydrate ContentPongamia pinnata: An Untapped Resource for the Biofuels Industry of the FutureEffects on Lignin Structure of Coumarate 3-Hydroxylase Downregulation in Poplar.Compositional Analysis of Biomass Reference Materials: Results from an Interlaboratory Study.Yield and Nutrient Removal by Bioenergy Grasses on Swine Effluent Spray Fields in the Coastal Plain Region of North CarolinaDedicated Herbaceous Biomass Feedstock Genetics and DevelopmentErratum to: Identification and Characterization of Four Missense Mutations in Brown midrib12 (Bmr12), the Caffeic acid O-Methyltranferase (COMT) of SorghumEvaluation of Public Sweet Sorghum A-Lines for Use in Hybrid ProductionIdentification and Characterization of Four Missense Mutations in Brown midrib 12 (Bmr12), the Caffeic O-Methyltranferase (COMT) of SorghumSwitchgrass Contains Two Cinnamyl Alcohol Dehydrogenases Involved in Lignin FormationImproved Sugar Conversion and Ethanol Yield for Forage Sorghum (Sorghum bicolor L. Moench) Lines with Reduced Lignin ContentsCharacterisation of Authentic Lignin Biorefinery Samples by Fourier Transform Infrared Spectroscopy and Determination of the Chemical Formula for LigninImproved Feedstock Option or Invasive Risk? Comparing Establishment and Productivity of Fertile Miscanthus × giganteus to Miscanthus sinensisGrass Invasion into Switchgrass Managed for Biomass EnergyBioenergy Feedstocks at Low Risk for Invasion in the USA: a “White List” ApproachInsufficient Evidence of Jatropha curcas L. Invasiveness: Experimental Observations in Burkina Faso, West AfricaAn Improved Tissue Culture System for Embryogenic Callus Production and Plant Regeneration in Switchgrass (Panicum virgatum L.)Assessment of Aboveground and Belowground Vegetative Fragments as Propagules in the Bioenergy Crops Arundo donax and Miscanthus × giganteusSecond Generation Biofuels: High-Efficiency Microalgae for Biodiesel ProductionEnvironmental Tolerances of Miscanthus sinensis in Invasive and Native PopulationsEffect of Potassium and Nitrogen Fertilizer on Switchgrass Productivity and Nutrient Removal Rates under Two Harvest Systems on a Low Potassium SoilRoot System Dynamics of Miscanthus × giganteus and Panicum virgatum in Response to Rainfed and Irrigated Conditions in CaliforniaSimultaneous Saccharification and Fermentation of Hydrothermal Pretreated Lignocellulosic Biomass: Evaluation of Process Performance Under Multiple Stress ConditionsConserving Open Natural Pollination Safeguards Jatropha Oil Yield and Oil QualityCarbon Inputs from Miscanthus Displace Older Soil Organic Carbon Without Inducing PrimingErratum to: Carbon Inputs from Miscanthus Displace Older Soil Organic Carbon Without Inducing PrimingCell Wall Composition and Bioenergy Potential of Rice Straw Tissues Are Influenced by Environment, Tissue Type, and GenotypeSignificant Contribution of Energy Crops to Heat and Electricity Needs in Great Britain to 2050An Investigation on the Economic Feasibility of Macroalgae as a Potential Feedstock for BiorefineriesGenomic Analysis of Xylose Metabolism in Members of the Deinoccocus-Thermus Phylum from Thermophilic Biomass-Deconstructing Bacterial ConsortiaHigh-Throughput Prediction of Acacia and Eucalypt Lignin Syringyl/Guaiacyl Content Using FT-Raman Spectroscopy and Partial Least Squares ModelingHow Alkyl Chain Length of Alcohols Affects Lignin Fractionation and Ionic Liquid Recycle During Lignocellulose PretreatmentImpact of Pretreatment Technologies on Saccharification and Isopentenol Fermentation of Mixed Lignocellulosic FeedstocksScale-Up of Ionic Liquid-Based Fractionation of Single and Mixed FeedstocksThe DOE Bioenergy Research Centers: History, Operations, and Scientific OutputAssessment of Lignocellulosic Biomass Using Analytical Spectroscopy: an Evolution to High-Throughput TechniquesComparing the Recalcitrance of Eucalyptus, Pine, and Switchgrass Using Ionic Liquid and Dilute Acid PretreatmentsMonitoring and Analyzing Process Streams Towards Understanding Ionic Liquid Pretreatment of Switchgrass (Panicum virgatum L.)
P1433
Q26768305-3097BB60-0B0A-4442-A8A8-35C334D743BDQ28601022-A3A331B3-EB9B-4CC7-B27C-D6E4ED62CECAQ28608033-950F7553-03BB-4451-B9F1-05D857E1E94EQ29036854-5A31A3AC-8B23-4484-A024-6D1E4E3A6AEFQ36027957-4B96127F-1F5D-4DF0-8E04-A4F771AF2735Q36727780-375736B5-13BD-40FD-9791-2ED7828FF051Q47036945-BB901743-A924-42D6-AD6B-62132F3FC054Q55113287-40CF0E4B-1273-44E7-ADE2-06BE1E8C80A3Q55113299-D9BFFEE0-D634-4BB2-9BCF-0674C0A7DB71Q55113301-AB0EC9A6-0502-4CA0-AAD5-6BD2A3652FC3Q55113308-B8CBAA02-7E4B-4D8D-BF09-CEB957E04975Q55113310-B3060752-FDF4-4B3C-B7FB-6DE2FA60A4A6Q55113315-0448647C-1CA4-4457-944E-921A51E42FEEQ56034956-14808D01-F006-4410-BBE5-0F0A55646142Q56332453-6687E299-6621-43BB-9E2A-6343DAB4D38BQ56418002-9ABB2157-59B1-4C8D-B5EA-05CAB1FD7C10Q56434074-8AF13C8E-3771-4745-B843-920CB08FA459Q56434078-E63FB359-8448-4C3B-9727-AF27DF150890Q56446350-796921AA-E526-4E6C-B8E7-5ACB802C9D16Q56505168-17702685-9A2A-40B5-8061-13054DCD214CQ56522471-8754A8C3-244A-467A-B2F4-A4E11082F6FAQ56571437-CF5996F9-4A85-4678-9D47-06E6FE6C2808Q56660009-941BB625-DF42-4A90-82FC-7A04ED5451CFQ56929344-FE6C8ED3-1A53-43B2-9618-05938FD6E934Q56955729-BCE40642-DBF1-49B3-AA15-932657689234Q57021508-2BE2104C-E1C2-46BA-8F41-D2E5C21371E9Q57027775-7DF0FC63-B1F4-43DE-94E5-BFF65394DA49Q57027780-E2B4022E-05E5-4F98-AADA-F0D52B276621Q57027963-C8380CCD-D1D6-4E08-9CD5-1719F25D8428Q57028406-67CEB78C-CEF1-4FE7-B1BD-20CC821B8E77Q57028535-BD234F81-4565-4C26-9D11-3598626EAFDDQ57028572-AA304AC4-4F75-465A-8F9C-3433EB3914A8Q57028578-A64970BB-41A2-4409-ADBA-4B72537F8231Q57028584-5CFAE87E-02D6-4D6A-A10E-B8F32463AAA3Q57028589-D944D793-13DB-4FE6-B15A-BC098F10CDF0Q57028604-20A056D4-2B1A-44DB-B63B-2A953B65AD06Q57028611-2449F208-7198-4F74-94FD-5B469620659FQ57028627-B48EA1F4-815B-4067-BC75-5AB03BDA62C7Q57028701-8F8ABC26-4604-4AC0-9490-DB716348C051Q57028893-09B150EE-875E-49C2-8A44-05D16A833DEA
P1433
description
journal
@en
revista científica
@es
rivista scientifica
@it
wetenschappelijk tijdschrift van Springer Science+Business Media
@nl
wissenschaftliche Fachzeitschrift
@de
name
Bioenergy research
@ast
Bioenergy research
@en
Bioenergy research
@es
Bioenergy research
@it
Bioenergy research
@nl
type
label
Bioenergy research
@ast
Bioenergy research
@en
Bioenergy research
@es
Bioenergy research
@it
Bioenergy research
@nl
prefLabel
Bioenergy research
@ast
Bioenergy research
@en
Bioenergy research
@es
Bioenergy research
@it
Bioenergy research
@nl
P3181
P1055
P1058
P1156
14700154701