nach oben

Mitigation and Adaptation Strategies for Global Change

Erschienen in:

01.12.2016 | Original Article

Managing the nitrogen cycle to reduce greenhouse gas emissions from crop production and biofuel expansion

verfasst von: Stephen M. Ogle, Bruce A. McCarl, Justin Baker, Stephen J. Del Grosso, Paul R. Adler, Keith Paustian, William J. Parton

Erschienen in: Mitigation and Adaptation Strategies for Global Change | Ausgabe 8/2016

Einloggen, um Zugang zu erhalten

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

Public policies are promoting biofuels as an alternative to fossil fuel consumption in order to mitigate greenhouse gas (GHG) emissions. However, the mitigation benefit can be at least partially compromised by emissions occurring during feedstock production. One of the key sources of GHG emissions from biofuel feedstock production, as well as conventional crops, is soil nitrous oxide (N₂O), which is largely driven by nitrogen (N) management. Our objective was to determine how much GHG emissions could be reduced by encouraging alternative N management practices through application of nitrification inhibitors and a cap on N fertilization. We used the US Renewable Fuel Standards (RFS2) as the basis for a case study to evaluate technical and economic drivers influencing the N management mitigation strategies. We estimated soil N₂O emissions using the DayCent ecosystem model and applied the US Forest and Agricultural Sector Optimization Model with Greenhouse Gases (FASOMGHG) to project GHG emissions for the agricultural sector, as influenced by biofuel scenarios and N management options. Relative to the current RSF2 policy with no N management interventions, results show decreases in N₂O emissions ranging from 3 to 4 % for the agricultural sector (5.5–6.5 million metric tonnes CO₂ eq. year⁻¹; 1 million metric tonnes is equivalent to a Teragram) in response to a cap that reduces N fertilizer application and even larger reductions with application of nitrification inhibitors, ranging from 9 to 10 % (15.5–16.6 million tonnes CO₂ eq. year⁻¹). The results demonstrate that climate and energy policies promoting biofuel production could consider options to manage the N cycle with alternative fertilization practices for the agricultural sector and likely enhance the mitigation of GHG emissions associated with biofuels.

Vorheriger Artikel Greenhouse gas scenarios for Austria: a comparison of different approaches to emission trends

Nächster Artikel Impact of urban water supply on energy use in China: a provincial and national comparison

Adams D, Alig R, McCarl BA, Murray BC (2005) FASOMGHG conceptual structure, and specification: documentation. http://agecon2.tamu.edu/people/faculty/mccarl-bruce/papers/1212FASOMGHG_doc.pdf. Cited 6 Aug 2014

Adler PR, Del Grosso SJ, Parton WJ (2007) Life cycle assessment of net greenhouse gas flux for bioenergy cropping systems. Ecol Appl 17:675–691CrossRef

Adler PR, Del Grosso SJ, Inman D et al (2012) Mitigation opportunities for life cycle greenhouse gas emissions during feedstock production across heterogeneous landscapes. In: Liebig M, Franzluebbers AJ, Follett RF (eds) Managing agricultural greenhouse gases: coordinated agricultural research through GRACEnet to address our changing climate. Elsevier Publishing, New York

Akaike H (1973) Information theory and an extension of the maximum likelihood principle. In: Petrov BN, Caski F (eds), Second international symposium on information theory, Budapest, Hungary, 2-8 September 1971, pp. 267–281

Akiyama H, Yan X, Yagi K (2010) Evaluation of effectiveness of enhanced-efficiency fertilizers as mitigation options for N₂O and NO emissions from agricultural soils: meta-analysis. Glob Chang Biol 16:1837–1846CrossRef

Antle J, Ogle SM (2012) Influence of soil C, N₂O and fuel use on GHG mitigation with no-till adoption. Clim Chang 111:609–625CrossRef

Baker JS, McCarl BA, Murray BC et al (2010) Net farm income and land use under a U.S. greenhouse gas cap-and-trade. AAEA Policy Issues 7:1–5

Baker JS, Murray BC, McCarl BA et al (2011) Greenhouse emissions and nitrogen use in U.S. agriculture: historic trends, future projections, and biofuel policy scenarios. NI R 11–08. Nicholas Institute Environmental Policy Solutions, Duke University, Durham

Baker JS, Murray BC, McCarl BA et al (2013) Implications of alternative agricultural productivity growth assumptions on land management, greenhouse gas emissions, and mitigation potential. Am J Agric Econ 95:435–441CrossRef

Beach RH, Adams DM, Alig RJ et al (2010) Model documentation for the Forest and Agricultural Sector Optimization Model with Greenhouse Gases (FASOMGHG). U.S. Environmental Protection Agency, Climate Change Division, Washington, D.C

Bouwman AF, van Grinsven JJM, Eickhout B (2010) Consequences of the cultivation of energy crops for the global nitrogen cycle. Ecol Appl 20:101–109CrossRef

Burnham KP, Anderson DR (2002) Model selection and multi-model inference: a practical information-theoretic approach, 2nd edn. Springer, New York, USA, p 488

Cavigelli MA, Mirsky SB, Teasdale JR et al (2013) Organic grain cropping systems to enhance ecosystem services. Renewable Agric Food Syst 28:145–159CrossRef

CBO (2009) The impact of ethanol use on food prices and greenhouse-gas emissions. The Congress of the United States. Congressional Budget Office, Washington, D.C

Conant RT, Berdanier AB, Grace PR (2013) Patterns and trends in nitrogen use and nitrogen recovery efficiency in world agriculture. Glob Biogeochem Cycles 27:558–566CrossRef

Crutzen PJ, Mosier AR, Smith KA, Winiwarter W (2008) N₂O release from agro-biofuel production negates global warming reduction by replacing fossil fuels. Atmos Chem Phys 8:389–395CrossRef

CTIC (2004) 2004 Crop residue management survey. Conservation Technology Information Center. Available online at <http://www.ctic.purdue.edu/CRM/>

Davidson EA (2009) The contribution of manure and fertilizer nitrogen to atmospheric nitrous oxide since 1860. Nat Geosci 2:659–662CrossRef

Davis SC, Parton WJ, Dohleman FG et al (2010) Comparative biogeochemical cycles of bioenergy crops reveal nitrogen-fixation and low greenhouse gas emissions in a Miscanthus * giganteus agro-ecosystem. Ecosystems 13:144–156CrossRef

Davis SC, Boddey RM, Alves BJR et al (2013) Management swing potential for bioenergy crops. GCB Bioenergy 5:623–638CrossRef

De Klein C, Novoa RSA, Ogle S et al (2006) N₂O emissions from managed soil, and CO₂ emissions from lime and urea application. In: Eggleston S, Buendia L, Miwa K, Ngara T, Tanabe K (eds) IPCC guidelines for national greenhouse gas inventories, Vol. 4: Agriculture, forestry and other land use. Intergovernmental Panel on Climate Change. National Greenhouse Gas Inventory Programme, IGES, Hayama, p 54

Del Grosso SJ, Mosier AR, Parton WJ, Ojima DS (2005) DAYCENT model analysis of past and contemporary soil N₂O and net greenhouse gas flux for major crops in the USA. Soil Tillage Res 83:9–24CrossRef

Del Grosso SJ, Parton WJ, Mosier AR et al (2006) DAYCENT national scale simulations of N₂O emissions from cropped soils in the USA. J Environ Qual 35:1451–1460CrossRef

Del Grosso SJ, Wirth T, Ogle SM, Parton WJ (2008) Estimating agricultural nitrous oxide emissions. Eos 89:529–530CrossRef

Del Grosso SJ, Ojima DS, Parton WJ et al (2009) Global Scale DAYCENT model analysis of greenhouse gas mitigation strategies for cropped soils. Glob Planet Chang 67:44–50CrossRef

Del Grosso S, Ogle SM, Parton WJ, Breidt FJ (2010) Estimating uncertainty in N₂O emissions from US cropland soils. Glob Biogeochem Cycles 24, GB1009

Elobeid A, Carriquiry M, Dumortier J et al (2013) Biofuel expansion, fertilizer use and GHG emissions: unintended consequences of mitigation policies. Econ Res Int 2013:708604. doi:10.1155/2013/708604

Erisman JW, van Grinsven H, Leip A, Mosier A, Bleeker A (2009) Nitrogen and biofuels; an overview of the current state of knowledge. Nutr Cycl Agroecosyst 86:211–223CrossRef

Firestone MK, Davidson EA (1989) Microbiological basis of NO and N₂O production and consumption in soil. In: Andreae MO, Schimel DS (eds) Exchange of trace gases between terrestrial ecosystems and the atmosphere. Wiley, New York

Halvorson AD, Del Grosso SJ, Alluvione F (2010) Tillage and inorganic nitrogen source effects on nitrous oxide emissions from irrigated cropping systems. SSSAJ 74:436–445CrossRef

Havlík P, Valin H, Herrero M et al (2014) Climate change mitigation through livestock system changes. Proc Natl Acad Sci 110:3709–3714CrossRef

Havlík P, Valin H, Mosnier A et al (2013) Crop productivity and the global livestock sector: implications for land use change and greenhouse gas emission. Am J Agric Econ 95:442–448

Homer C, Dewitz J, Fry J et al (2007) Completion of the 2001 National Land Cover Database for the conterminous United States. Photogramm Eng Remote Sens 73:337–341

IPCC (2014) Agriculture, forestry, and other land use (AFOLU). In: Edenhofer O, Pichs-Madruga R, Sokona Y et al (eds) Mitigation of climate change. Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, p 181

Johnson DM, Mueller R (2010) The 2009 cropland data layer. Photogramm Eng Remote Sens 76:1201–1205

Kim S, Dale BE (2009) Regional variations in greenhouse gas emissions of biobased products in the United States-corn-based ethanol and soybean oil. Int J Life Cycle Assess 14:540–546CrossRef

Laboski C (2006) Does it pay to use nitrification and urease inhibitors? In Proceedings of the Wisconsin Fertilizer, AgLime & Pest Management Conference, Volume 45, pp.44–50

Liu XJ, Mosier AR, Halvorson AD, Zhang FS (2006) The impact of nitrogen placement and tillage on NO, N₂O, CH₄ and CO₂ fluxes from a clay loam soil. Plant Soil 280:177–188CrossRef

McCarl BA, Schneider UA (2001) Greenhouse gas mitigation in US Agriculture and Forestry. Science 294:2481–2482CrossRef

Mellilo JM, Reilly JM, Kicklighter DW, Gurgel AC, Cronin TW, Paltsev S, Felzer BS, Wang X, Sokolov AP, Schlosser CA (2009) Indirect emissions from biofuels: how important? Science 326:1397–1399

Mitchell R, Vogel KP, Sarath G (2008) Managing and enhancing switchgrass as a bioenergy feedstock. Biofuels Bioprod Biorefin 2:530–539CrossRef

Mosier AR, Duxbury JM, Freney JR, Heinemeyer O, Minami K (1998) Assessing and mitigating N₂O emissions from agricultural soils. Clim Chang 40:7–38

Mosnier A, Havlk P, Valin H et al (2013) Alternative U.S. biofuel mandates and global GHG emissions: the role of land use change, crop management and yield growth. Energy Policy 57:602–614CrossRef

Murray BC, Sommer AJ, Depro B (2005) Greenhouse gas mitigation potential in US Forestry and Agriculture. US Environmental Protection Agency, Washington, D.C, Report 430-R-05-006

Parton WJ, Hartman MD, Ojima DS, Schimel DS (1998) DAYCENT: its land surface submodel: description and testing. Glob Planet Chang 19:35–48CrossRef

Piñeiro G, Jobbagy EG, Baker JS et al (2009) Set-asides can be better climate investment than corn ethanol. Ecol Appl 19:277–282CrossRef

Pinheiro JC, Bates DM (2000) Mixed-effect models in S and S-Plus. Springer, New York, p 528CrossRef

Ravishankara AR, Daniel JS, Portmann RW (2009) Nitrous oxide (N₂O): the dominant ozone-depleting substance emitted in the 21st century. Science 326:123–125

Robertson GP, Vitousek PM (2009) Nitrogen in agriculture: balancing the cost of an essential resource. Annu Rev Environ Resour 34:97–125CrossRef

Saxton KE, Rawls WJ, Romberger JS, Papendick RI (1986) Estimating generalized soil-water characteristics from texture. SSSAJ 50:1031–1036CrossRef

Scharlemann JPW, Laurance WF (2008) How green are biofuels? Science 319:43–44

Schou J, Skop E, Jensen J (2000) Integrated agr-environmental modeling: a cost-effectiveness analysis of two nitrogen tax instruments in the Vejle Fjord watershed, Denmark. J Environ Manag 58:199–212CrossRef

Smith P, Martino D, Cai Z et al (2007) Greenhouse gas mitigation in agriculture. Phil Trans R Soc B. doi:10.1098/rstb.2007.2184

Thornton PE, Running SW (1999) An improved algorithm for estimating incident daily solar radiation from measurements of temperature, humidity, and precipitation. Agric Forest Meteorol 93:211–228CrossRef

Thornton PE, Running SW, White MA (1997) Generating surfaces of daily meteorology variables over large regions of complex terrain. J Hydrol 190:214–251CrossRef

Thornton PE, Hasenauer H, White MA (2000) Simultaneous estimation of daily solar radiation and humidity from observed temperature and precipitation: an application over complex terrain in Austria. Agric For Meteorol 104:255–271CrossRef

USDA-ERS (1997) Cropping Practices Survey Data—1995. Research Service, United States Department of Agriculture, Washington, D.C

USDA-NASS (2010) Crop Production Summary, National Agricultural Statistics Service, Agricultural Statistics Board, U.S. Department of Agriculture, Washington, DC, http://usda.mannlib.cornell.edu/MannUsda/viewDocumentInfo.do?documentID=1047

US-EPA (2010a) Inventory of U.S. greenhouse gas emissions and sinks: 1990–2008. US Environmental Protection Agency, Office of Atmospheric Programs, Washington, D.C., p 407, EPA 430-R-10-006

US-EPA (2010b) Supplemental EPA Analysis of the American Clean Energy and Security Act of 2009. H.R. 2454 in the 111th Congress. US Environmental Protection Agency, Office of Atmospheric Programs, Washington, D.C., p 53

US-EPA (2014) Inventory of U.S. greenhouse gas emissions and sinks: 1990-2012. United States Environmental Protection Agency, EPA 430-R-14-003, Washington, DC.

Venterea RT, Burger M, Spokas KA (2005) Nitrogen oxide and methane emissions under varying tillage and fertilizer management. J Environ Qual 34:1467–1477CrossRef

Zah R, Böni H, Gauch M et al (2007) Life cycle assessment of energy products: environmental impact assessment of biofuels. EMPA, St. Gallen

Titel: Managing the nitrogen cycle to reduce greenhouse gas emissions from crop production and biofuel expansion
verfasst von: Stephen M. Ogle
Bruce A. McCarl
Justin Baker
Stephen J. Del Grosso
Paul R. Adler
Keith Paustian
William J. Parton
Publikationsdatum: 01.12.2016
Verlag: Springer Netherlands
Erschienen in: Mitigation and Adaptation Strategies for Global Change / Ausgabe 8/2016
Print ISSN: 1381-2386
Elektronische ISSN: 1573-1596
DOI: https://doi.org/10.1007/s11027-015-9645-0

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Weitere Artikel der Ausgabe 8/2016

Costs and benefits of differences in the timing of greenhouse gas emission reductions

A numerical modeling approach to support decision-making on design of integrated multitrophic aquaculture for efficiently mitigating aquatic waste

Greenhouse gas scenarios for Austria: a comparison of different approaches to emission trends

Impact of urban water supply on energy use in China: a provincial and national comparison

Water security as a challenge for the sustainability of La Serena-Coquimbo conurbation in northern Chile: global perspectives and adaptation

Assessing agricultural systems vulnerability to climate change to inform adaptation planning: an application in Khorezm, Uzbekistan