| P50 | author | Goetz M Richter | Q61828641 |
| | Niall P McNamara | Q63390131 |
| | Iain Donnison | Q42321415 |
| | Paul Robson | Q56977347 |
| | Jon McCalmont | Q57306761 |
| P2093 | author name string | Astley Hastings | |
| | John Clifton-Brown | |
| P2860 | cites work | Changes in soil organic carbon under biofuel crops | Q57936034 |
| | Comparative Biogeochemical Cycles of Bioenergy Crops Reveal Nitrogen-Fixation and Low Greenhouse Gas Emissions in a Miscanthus × giganteus Agro-Ecosystem | Q57936041 |
| | Comparative analysis of hydrologic signatures in two agricultural watersheds in east-central Illinois: legacies of the past to inform the future | Q58069533 |
| | Nitrous oxide emissions from managed grassland: a comparison of eddy covariance and static chamber measurements | Q58078085 |
| | Is UK biofuel supply fromMiscanthuswater-limited? | Q58241068 |
| | Water-use efficiency of willow: Variation with season, humidity and biomass allocation | Q58243307 |
| | Soil carbon stocks and bulk density: spatial or cumulative mass coordinates as a basis of expression? | Q58317386 |
| | Interactions between the Grasses Phalaris arundinacea, Miscanthus sinensis and Echinochloa crus-galli, and Barley and Cereal Yellow Dwarf Viruses | Q58318144 |
| | Water use efficiency of short-rotation Salix viminalis at leaf, tree and stand scales | Q75827947 |
| | Modelling supply and demand of bioenergy from short rotation coppice and Miscanthus in the UK | Q84562688 |
| | N₂O release from agro-biofuel production negates global warming reduction by replacing fossil fuels | Q21093467 |
| | Use of U.S. Croplands for Biofuels Increases Greenhouse Gases Through Emissions from Land-Use Change | Q24289134 |
| | Carbon Sequestration by Perennial Energy Crops: Is the Jury Still Out? | Q26768305 |
| | Acceleration of global warming due to carbon-cycle feedbacks in a coupled climate model | Q28138410 |
| | Potential impacts on ecosystem services of land use transitions to second-generation bioenergy crops in GB | Q28598230 |
| | Global food demand and the sustainable intensification of agriculture | Q28740557 |
| | Carbon debt of Conservation Reserve Program (CRP) grasslands converted to bioenergy production | Q28741257 |
| | Food security and sustainable intensification | Q30389142 |
| | Azospirillum doebereinerae sp. nov., a nitrogen-fixing bacterium associated with the C4-grass Miscanthus | Q30633125 |
| | Energy. Beneficial biofuels--the food, energy, and environment trilemma | Q34992687 |
| | Prospects for arable farm uptake of Short Rotation Coppice willow and miscanthus in England. | Q36944356 |
| | Novel endophytic nitrogen-fixing clostridia from the grass Miscanthus sinensis as revealed by terminal restriction fragment length polymorphism analysis | Q40279373 |
| | Miscanthus and switchgrass production in central Illinois: impacts on hydrology and inorganic nitrogen leaching | Q42839024 |
| | Bioenergy production from perennial energy crops: a consequential LCA of 12 bioenergy scenarios including land use changes. | Q47816637 |
| | Production of first and second generation biofuels: A comprehensive review | Q56002352 |
| | Nitrogen deposition and its contribution to nitrogen cycling and associated soil processes | Q56069230 |
| | Priming effects: Interactions between living and dead organic matter | Q56483631 |
| | Yield-biodiversity trade-off in patchy fields ofMiscanthus × giganteus | Q57015751 |
| | Estimating UK perennial energy crop supply using farm-scale models with spatially disaggregated data | Q57028362 |
| | The technical potential of Great Britain to produce ligno-cellulosic biomass for bioenergy in current and future climates | Q57028472 |
| | Food vs. fuel: the use of land for lignocellulosic ‘next generation’ energy crops that minimize competition with primary food production | Q57028647 |
| | Global agriculture and nitrous oxide emissions | Q57028654 |
| | Future energy potential ofMiscanthusin Europe | Q57029096 |
| | Greenhouse gas emissions from four bioenergy crops in England and Wales: Integrating spatial estimates of yield and soil carbon balance in life cycle analyses | Q57029104 |
| | The potential ofMiscanthusto sequester carbon in soils: comparing field measurements in Carlow, Ireland to model predictions | Q57029158 |
| | Potential of Miscanthus grasses to provide energy and hence reduce greenhouse gas emissions | Q57029203 |
| | Global soil carbon: understanding and managing the largest terrestrial carbon pool | Q57031886 |
| | Untangling the confusion around land carbon science and climate change mitigation policy | Q57198192 |
| | Seasonal dynamics of above- and below-ground biomass and nitrogen partitioning in Miscanthus × giganteus and Panicum virgatum across three growing seasons | Q57202286 |
| | Seasonal nitrogen dynamics ofMiscanthus×giganteusandPanicum virgatum | Q57202307 |
| | Meeting US biofuel goals with less land: the potential of Miscanthus | Q57202316 |
| | Soil-derived trace gas fluxes from different energy crops - results from a field experiment in Southwest Germany | Q57239015 |
| | From set-aside grassland to annual and perennial cellulosic biofuel crops: Effects of land use change on carbon balance | Q57597133 |
| | Whole-Profile Soil Carbon Stocks: The Danger of Assuming Too Much from Analyses of Too Little | Q57597170 |
| P433 | issue | 3 | |
| P304 | page(s) | 489-507 | |
| P577 | publication date | 2015-08-18 | |
| P1433 | published in | GCB Bioenergy | Q19720862 |
| P1476 | title | Environmental costs and benefits of growing Miscanthus for bioenergy in the UK | |
| P478 | volume | 9 | |