Environmental costs and benefits of growing Miscanthus for bioenergy in the UK

Planting the perennial biomass crop Miscanthus in the UK could offset 2–13 Mt oil eq. yr−1, contributing up to 10% of current energy use. Policymakers need assurance that upscaling Miscanthus production can be performed sustainably without negatively impacting essential food production or the wider environment. This study reviews a large body of Miscanthus relevant literature into concise summary statements. Perennial Miscanthus has energy output/input ratios 10 times higher (47.3 ± 2.2) than annual crops used for energy (4.7 ± 0.2 to 5.5 ± 0.2), and the total carbon cost of energy production (1.12 g CO2‐C eq. MJ−1) is 20–30 times lower than fossil fuels. Planting on former arable land generally increases soil organic carbon (SOC) with Miscanthus sequestering 0.7–2.2 Mg C4‐C ha−1 yr−1. Cultivation on grassland can cause a disturbance loss of SOC which is likely to be recovered during the lifetime of the crop and is potentially mitigated by fossil fuel offset. N2O emissions can be five times lower under unfertilized Miscanthus than annual crops and up to 100 times lower than intensive pasture. Nitrogen fertilizer is generally unnecessary except in low fertility soils. Herbicide is essential during the establishment years after which natural weed suppression by shading is sufficient. Pesticides are unnecessary. Water‐use efficiency is high (e.g. 5.5–9.2 g aerial DM (kg H2O)−1, but high biomass productivity means increased water demand compared to cereal crops. The perennial nature and belowground biomass improves soil structure, increases water‐holding capacity (up by 100–150 mm), and reduces run‐off and erosion. Overwinter ripening increases landscape structural resources for wildlife. Reduced management intensity promotes earthworm diversity and abundance although poor litter palatability may reduce individual biomass. Chemical leaching into field boundaries is lower than comparable agriculture, improving soil and water habitat quality.

[1]  Rural Affairs Agriculture in the United Kingdom , 2018 .

[2]  A. P. Williams,et al.  Consequential life cycle assessment of biogas, biofuel and biomass energy options within an arable crop rotation , 2015 .

[3]  Gail Taylor,et al.  Potential impacts on ecosystem services of land use transitions to second‐generation bioenergy crops in GB , 2015, Global change biology. Bioenergy.

[4]  J. Dauber,et al.  Yield‐biodiversity trade‐off in patchy fields of Miscanthus × giganteus , 2015 .

[5]  Rodger P. White,et al.  Sequestration of C in soils under Miscanthus can be marginal and is affected by genotype-specific root distribution , 2015 .

[6]  J. Burke,et al.  Are the benefits of yield responses to nitrogen fertilizer application in the bioenergy crop Miscanthus × giganteus offset by increased soil emissions of nitrous oxide? , 2015 .

[7]  A. Kent,et al.  Contribution of nitrogen fixation to first year Miscanthus × giganteus , 2014 .

[8]  Andrew B. Riche,et al.  The yield and quality response of the energy grass Miscanthus × giganteus to fertiliser applications of nitrogen, potassium and sulphur , 2014 .

[9]  A. Hastings,et al.  Land use change from C3 grassland to C4 Miscanthus: effects on soil carbon content and estimated mitigation benefit after six years , 2014 .

[10]  A. Don,et al.  Soil carbon changes under Miscanthus driven by C4 accumulation and C3 decompostion – toward a default sequestration function , 2014 .

[11]  H. Godfray,et al.  Food security and sustainable intensification , 2014, Philosophical Transactions of the Royal Society B: Biological Sciences.

[12]  A. Lovett,et al.  The availability of land for perennial energy crops in Great Britain , 2014 .

[13]  Pete Smith,et al.  Estimating UK perennial energy crop supply using farm‐scale models with spatially disaggregated data , 2014 .

[14]  Gail Taylor,et al.  The technical potential of Great Britain to produce ligno‐cellulosic biomass for bioenergy in current and future climates , 2014 .

[15]  Roland Hiederer,et al.  Global soil carbon: understanding and managing the largest terrestrial carbon pool , 2014 .

[16]  S. Hamilton,et al.  From set-aside grassland to annual and perennial cellulosic biofuel crops: Effects of land use change on carbon balance , 2013 .

[17]  Ximing Cai,et al.  Comparative analysis of hydrologic signatures in two agricultural watersheds in east-central Illinois: legacies of the past to inform the future , 2013 .

[18]  MICHAEL B. Jones,et al.  The Effects of Land-Use Change from Grassland to Miscanthus x giganteus on Soil N 2 O Emissions , 2013 .

[19]  Daniel Felten,et al.  Energy balances and greenhouse gas-mitigation potentials of bioenergy cropping systems (Miscanthus, rapeseed, and maize) based on farming conditions in Western Germany , 2013 .

[20]  N. J. Glithero,et al.  Prospects for arable farm uptake of Short Rotation Coppice willow and miscanthus in England , 2013, Applied energy.

[21]  David B. Lindenmayer,et al.  Untangling the confusion around land carbon science and climate change mitigation policy , 2013 .

[22]  Min Chen,et al.  Biofuel, land and water: maize, switchgrass or Miscanthus? , 2013 .

[23]  Gail Taylor,et al.  Development and evaluation of ForestGrowth‐SRC a process‐based model for short rotation coppice yield and spatial supply reveals poplar uses water more efficiently than willow , 2013 .

[24]  H. Wenzel,et al.  Bioenergy production from perennial energy crops: a consequential LCA of 12 bioenergy scenarios including land use changes. , 2012, Environmental science & technology.

[25]  Christoph Emmerling,et al.  Accumulation of Miscanthus-derived carbon in soils in relation to soil depth and duration of land use under commercial farming conditions , 2012 .

[26]  F. Dohleman,et al.  Seasonal dynamics of above‐ and below‐ground biomass and nitrogen partitioning in Miscanthus × giganteus and Panicum virgatum across three growing seasons , 2012 .

[27]  A. Hastings,et al.  Land‐use change to bioenergy production in Europe: implications for the greenhouse gas balance and soil carbon , 2012 .

[28]  J. Dauber,et al.  Soil carbon sequestration during the establishment phase of Miscanthus × giganteus: a regional‐scale study on commercial farms using 13C natural abundance , 2012 .

[29]  Ute Skiba,et al.  How do soil emissions of N2O, CH4 and CO2 from perennial bioenergy crops differ from arable annual crops? , 2012 .

[30]  Keith A. Smith,et al.  Global agriculture and nitrous oxide emissions , 2012 .

[31]  K. Butterbach‐Bahl,et al.  Soil‐derived trace gas fluxes from different energy crops – results from a field experiment in Southwest Germany , 2012 .

[32]  T. Voigt,et al.  Greenhouse Gas Emissions, Nitrate Leaching, and Biomass Yields from Production of Miscanthus × giganteus in Illinois, USA , 2012, BioEnergy Research.

[33]  J. Machet,et al.  Nutrient requirements of Miscanthus x giganteus: Conclusions from a review of published studies , 2012 .

[34]  A. Hastings,et al.  Food vs. fuel: the use of land for lignocellulosic ‘next generation’ energy crops that minimize competition with primary food production , 2012 .

[35]  D. Tilman,et al.  Global food demand and the sustainable intensification of agriculture , 2011, Proceedings of the National Academy of Sciences.

[36]  R. Rees,et al.  Nitrous oxide emissions from managed grassland: a comparison of eddy covariance and static chamber measurements , 2011 .

[37]  Christoph Emmerling,et al.  Effects of bioenergy crop cultivation on earthworm communities—A comparative study of perennial (Miscanthus) and annual crops with consideration of graded land-use intensity , 2011 .

[38]  Ilya Gelfand,et al.  Carbon debt of Conservation Reserve Program (CRP) grasslands converted to bioenergy production , 2011, Proceedings of the National Academy of Sciences.

[39]  R. Clift,et al.  Soil Organic Carbon Changes in the Cultivation of Energy Crops: Implications for GHG Balances and Soil Quality for Use in LCA , 2011 .

[40]  Mareike Lange,et al.  The GHG Balance of Biofuels Taking into Account Land Use Change (Power Point) , 2011 .

[41]  Gerard Kiely,et al.  Nitrous Oxide Emission from Grazed Grassland Under Different Management Systems , 2011, Ecosystems.

[42]  Uffe Jørgensen,et al.  Benefits versus risks of growing biofuel crops: the case of Miscanthus , 2011 .

[43]  Geoffrey P. Hammond,et al.  Barriers to and drivers for UK bioenergy development , 2011 .

[44]  Matthew J. Aylott,et al.  Modelling supply and demand of bioenergy from short rotation coppice and Miscanthus in the UK. , 2010, Bioresource technology.

[45]  G. McIsaac,et al.  Miscanthus and switchgrass production in central Illinois: impacts on hydrology and inorganic nitrogen leaching. , 2010, Journal of environmental quality.

[46]  Y. Kuzyakov Priming effects : interactions between living and dead organic matter , 2010 .

[47]  Carl J. Bernacchi,et al.  The impacts of Miscanthus×giganteus production on the Midwest US hydrologic cycle , 2010 .

[48]  Anthony G Williams,et al.  Environmental burdens of producing bread wheat, oilseed rape and potatoes in England and Wales using simulation and system modelling , 2010 .

[49]  W. Landman Climate change 2007: the physical science basis , 2010 .

[50]  L. Covarelli,et al.  First report of Miscanthus × giganteus rhizome rot caused by Fusarium avenaceum, Fusarium oxysporum and Mucor hiemalis , 2010, Australasian Plant Disease Notes.

[51]  R Arundale,et al.  First Report of Pithomyces chartarum Causing a Leaf Blight of Miscanthus × giganteus in Kentucky. , 2010, Plant disease.

[52]  Humberto Blanco-Canqui,et al.  Energy Crops and Their Implications on Soil and Environment , 2010 .

[53]  Prasant Kumar Rout,et al.  Production of first and second generation biofuels: A comprehensive review , 2010 .

[54]  Evan H. DeLucia,et al.  Comparative Biogeochemical Cycles of Bioenergy Crops Reveal Nitrogen-Fixation and Low Greenhouse Gas Emissions in a Miscanthus × giganteus Agro-Ecosystem , 2010, Ecosystems.

[55]  Marta Dondini,et al.  The potential of Miscanthus to sequester carbon in soils: comparing field measurements in Carlow, Ireland to model predictions , 2009 .

[56]  M. Dondini,et al.  Carbon sequestration under Miscanthus: a study of 13C distribution in soil aggregates , 2009 .

[57]  W. Cheng Rhizosphere priming effect: Its functional relationships with microbial turnover, evapotranspiration, and C–N budgets , 2009 .

[58]  Matthew J. Aylott,et al.  Greenhouse gas emissions from four bioenergy crops in England and Wales: Integrating spatial estimates of yield and soil carbon balance in life cycle analyses , 2009 .

[59]  Stephen P. Long,et al.  Seasonal nitrogen dynamics of Miscanthus×giganteus and Panicum virgatum , 2009 .

[60]  L. Lynd,et al.  Beneficial Biofuels—The Food, Energy, and Environment Trilemma , 2009, Science.

[61]  Christoph Emmerling,et al.  Decomposition and mineralization of energy crop residues governed by earthworms , 2009 .

[62]  Francesco Cherubini,et al.  Energy- and greenhouse gas-based LCA of biofuel and bioenergy systems: Key issues, ranges and recommendations , 2009 .

[63]  A. Hastings,et al.  Future energy potential of Miscanthus in Europe , 2009 .

[64]  K. McDonnell,et al.  Nitrate leaching losses from Miscanthus × giganteus impact on groundwater quality. , 2009 .

[65]  S. Hinsley,et al.  The impact of growing miscanthus for biomass on farmland bird populations , 2009 .

[66]  A. Lovett,et al.  Land Use Implications of Increased Biomass Production Identified by GIS-Based Suitability and Yield Mapping for Miscanthus in England , 2009, BioEnergy Research.

[67]  Andrew B. Riche,et al.  Growth, yield and mineral content of Miscanthus × giganteus grown as a biofuel for 14 successive harvests , 2008 .

[68]  A. Hastings,et al.  Potential of Miscanthus grasses to provide energy and hence reduce greenhouse gas emissions , 2008, Agronomy for Sustainable Development.

[69]  Stephen P. Long,et al.  Meeting US biofuel goals with less land: the potential of Miscanthus , 2008 .

[70]  Salvador A. Gezan,et al.  Is UK biofuel supply from Miscanthus water‐limited? , 2008 .

[71]  D. Moran,et al.  Farm-level constraints on the domestic supply of perennial energy crops in the UK , 2008 .

[72]  P. Rochette,et al.  Chamber Measurements of Soil Nitrous Oxide Flux: Are Absolute Values Reliable? , 2008 .

[73]  Jacinto F. Fabiosa,et al.  Use of U.S. Croplands for Biofuels Increases Greenhouse Gases Through Emissions from Land-Use Change , 2008, Science.

[74]  David Styles,et al.  Energy crops in Ireland: Quantifying the potential life-cycle greenhouse gas reductions of energy-crop electricity , 2007 .

[75]  John Clifton-Brown,et al.  Carbon mitigation by the energy crop, Miscanthus , 2007 .

[76]  Yakov Kuzyakov,et al.  Carbon sequestration under Miscanthus in sandy and loamy soils estimated by natural 13C abundance , 2007 .

[77]  Iris Lewandowski,et al.  Nitrogen, energy and land use efficiencies of miscanthus, reed canary grass and triticale as determined by the boundary line approach , 2006 .

[78]  D. G. Christian,et al.  The recovery over several seasons of 15N-labelled fertilizer applied to Miscanthus×giganteus ranging from 1 to 3 years old , 2006 .

[79]  B. Dale,et al.  Life cycle assessment of various cropping systems utilized for producing biofuels: Bioethanol and biodiesel , 2005 .

[80]  K. Minamisawa,et al.  Novel Endophytic Nitrogen-Fixing Clostridia from the Grass Miscanthus sinensis as Revealed by Terminal Restriction Fragment Length Polymorphism Analysis , 2004, Applied and Environmental Microbiology.

[81]  R. Lal Soil carbon sequestration to mitigate climate change , 2004 .

[82]  J. Clifton-Brown,et al.  Miscanthus biomass production for energy in Europe and its potential contribution to decreasing fossil fuel carbon emissions , 2004 .

[83]  Kristian Kristensen,et al.  Carbon sequestration in soil beneath long-term Miscanthus plantations as determined by 13C abundance , 2004 .

[84]  M. Roderick,et al.  Soil carbon stocks and bulk density: spatial or cumulative mass coordinates as a basis of expression? , 2003 .

[85]  J. Scurlock,et al.  The development and current status of perennial rhizomatous grasses as energy crops in the US and Europe , 2003 .

[86]  M. Shaw,et al.  Interactions between the Grasses Phalaris arundinacea, Miscanthus sinensis and Echinochloa crus-galli, and Barley and Cereal Yellow Dwarf Viruses , 2003 .

[87]  P. Leinweber,et al.  Cropping of Miscanthus in Central Europe: biomass production and influence on nutrients and soil organic matter , 2001 .

[88]  J. Knox,et al.  Review of the effects of energy crops on hydrology , 2001 .

[89]  Sebastian A. Leidel,et al.  Functional genomic analysis of cell division in C. elegans using RNAi of genes on chromosome III , 2000, Nature.

[90]  R. Betts,et al.  Acceleration of global warming due to carbon-cycle feedbacks in a coupled climate model , 2000, Nature.

[91]  John Clifton-Brown,et al.  Water Use Efficiency and Biomass Partitioning of Three Different Miscanthus Genotypes with Limited and Unlimited Water Supply , 2000 .

[92]  J. Morison,et al.  Water use efficiency of C4 perennial grasses in a temperate climate , 1999 .

[93]  K. O’Donnell,et al.  Fusarium miscanthi sp. nov. from Miscanthus litter , 1999 .

[94]  Andrew B. Riche,et al.  Nitrate leaching losses under Miscanthus grass planted on a silty clay loam soil , 1998 .

[95]  Steven R. Evett,et al.  Evapotranspiration and Yield of Corn Grown on Three High Plains Soils , 1998 .

[96]  D. Murphy,et al.  Nitrogen deposition and its contribution to nitrogen cycling and associated soil processes , 1998 .

[97]  G. Velthof,et al.  Nitrous oxide emissions from grazed grassland , 1997 .

[98]  K. A. Smith,et al.  Nitrous oxide emissions from fertilised grassland: A 2-year study of the effects of N fertiliser form and environmental conditions , 1997, Biology and Fertility of Soils.

[99]  Rasmus Nyholm Jørgensen,et al.  N2O emission from energy crop fields of Miscanthus “Giganteus” and winter rye , 1997 .

[100]  Pete Smith,et al.  Potential for carbon sequestration in European soils: preliminary estimates for five scenarios using results from long‐term experiments , 1997 .

[101]  G. Velthof,et al.  Seasonal variations in nitrous oxide losses from managed grasslands in The Netherlands , 1996, Plant and Soil.

[102]  D. G. Christian,et al.  First report of barley yellow dwarf luteovirus onMiscanthus in the United Kingdom , 1994, European Journal of Plant Pathology.

[103]  Sven Halldin,et al.  Water-use efficiency of willow: Variation with season, humidity and biomass allocation , 1994 .

[104]  J. Waines,et al.  Variation in Water‐Use Efficiency and Its Components in Wheat: I. Well‐Watered Pot Experiment , 1993 .

[105]  R. Houghton,et al.  The global carbon cycle. , 1988, Science.

[106]  Stephen P. Long,et al.  C4 photosynthesis at low temperatures , 1983 .

[107]  Mary Ann Curran,et al.  Consequential Life Cycle Assessment , 2017 .

[108]  G. Robertson,et al.  Whole-Profile Soil Carbon Stocks: The Danger of Assuming Too Much from Analyses of Too Little , 2011 .

[109]  Thomas B. Voigt,et al.  Miscanthus: A Promising Biomass Crop , 2010 .

[110]  C. Turley Intergovernmental Panel on Climate Change (IPCC) , 2010 .

[111]  E. Va,et al.  Changes in soil organic carbon under biofuel crops , 2009 .

[112]  F. Slater,et al.  The biodiversity of established biomass grass crops. , 2008 .

[113]  Frederick Maurice Slater,et al.  Ground flora, small mammal and bird species diversity in miscanthus (Miscanthus×giganteus) and reed canary-grass (Phalaris arundinacea) fields , 2007 .

[114]  Frederick Maurice Slater,et al.  Invertebrate populations in miscanthus (Miscanthus×giganteus) and reed canary-grass (Phalaris arundinacea) fields , 2007 .

[115]  Dželetović Željko,et al.  Miscanthus: European experience with a novel energy crop , 2007 .

[116]  under a Creative Commons License. Atmospheric Chemistry and Physics Discussions , 2005 .

[117]  D. Clark,et al.  The hydrological impacts of energy crop production in the UK. Final report , 2004 .

[118]  A. Hartmann,et al.  Azospirillum doebereinerae sp. nov., a nitrogen-fixing bacterium associated with the C4-grass Miscanthus. , 2001, International journal of systematic and evolutionary microbiology.

[119]  E. Cienciala,et al.  Water use efficiency of short-rotation Salix viminalis at leaf, tree and stand scales. , 1996, Tree physiology.

[120]  N. O'neill,et al.  Miscanthus blight, a new foliar disease of ornamental grasses and sugarcane incited by Leptosphaeria sp. and its anamorphic state Stagonospora sp , 1996 .

[121]  André Mariotti,et al.  Natural 13C abundance as a tracer for studies of soil organic matter dynamics , 1987 .

[122]  Göran I. Ågren,et al.  Theoretical analysis of decomposition of heterogeneous substrates , 1985 .

[123]  I. Abbott,et al.  Interactions between earthworms and their soil environment , 1981 .

[124]  Rothamsted Repository Download , 2022 .