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Evaluation of land use based greenhouse gas mitigation measures in Germany

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  • Röder, Norbert
  • Henseler, Martin
  • Liebersbach, Horst
  • Kreins, Peter
  • Osterburg, Bernhard

Abstract

Agricultural production contributes 11% to the total German greenhouse gas (GHG) emissions. We evaluate the efficiency of three different land use based GHG mitigation measures: production of feedstocks for biomethane production, short rotation coppices and peatland restoration. We evaluate these measures with respect to cost efficiency (GHG mitigation costs), mitigation potential and impact on agricultural production. We use the regional supply model RAUMIS to investigate the different mitigation measures at the sector and regional level. We extended the modeling framework of RAUMIS to integrate the effects of leakage and indirect land use change. Compared to the production and use of feedstock for bio-energies, peatland restoration is the most cost efficient measure and has the least impact on German agricultural production.

Suggested Citation

  • Röder, Norbert & Henseler, Martin & Liebersbach, Horst & Kreins, Peter & Osterburg, Bernhard, 2014. "Evaluation of land use based greenhouse gas mitigation measures in Germany," 2014 International Congress, August 26-29, 2014, Ljubljana, Slovenia 182674, European Association of Agricultural Economists.
  • Handle: RePEc:ags:eaae14:182674
    DOI: 10.22004/ag.econ.182674
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    1. Osterburg, Bernhard & Nieberg, Hiltrud & Ruter, Sebastian & Isermeyer, Folkhard & Haenel, Hans-Dieter & Hahne, Jochen & Krentler, Jan-Gerd & Paulsen, Hans Marten & Schuchardt, Frank & Schweinle, Jorg , 2009. "Erfassung, Bewertung und Minderung von Treibhausgasemissionen des deutschen Agrar- und Ernährungssektors," Thünen Working Paper 103666, Johann Heinrich von Thünen-Institut (vTI), Federal Research Institute for Rural Areas, Forestry and Fisheries.
    2. Ilya Gelfand & Ritvik Sahajpal & Xuesong Zhang & R. César Izaurralde & Katherine L. Gross & G. Philip Robertson, 2013. "Sustainable bioenergy production from marginal lands in the US Midwest," Nature, Nature, vol. 493(7433), pages 514-517, January.
    3. Dominic Moran & Michael Macleod & Eileen Wall & Vera Eory & Alistair McVittie & Andrew Barnes & Robert Rees & Cairistiona F. E. Topp & Andrew Moxey, 2011. "Marginal Abatement Cost Curves for UK Agricultural Greenhouse Gas Emissions," Journal of Agricultural Economics, Wiley Blackwell, vol. 62(1), pages 93-118, February.
    4. Rösemann, Claus & Haenel, Hans-Dieter & Dämmgen, Ulrich & Poddey, Eike & Freibauer, Annette & Wulf, Sebastian & Eurich-Menden, Brigitte & Döhler, Helmut & Schreiner, Carsten & Bauer, Beate & Osterburg, 2013. "Calculations of gaseous and particulate emissions from German agriculture 1990 - 2011. Report on methods and data (RMD) submission 2013 [Berechnung von gas- und partikelförmigen Emissionen aus der ," Thünen Reports 1, Johann Heinrich von Thünen Institute, Federal Research Institute for Rural Areas, Forestry and Fisheries.
    5. Thomas Fellmann & Ignacio Perez Dominguez & Heinz Peter Witzke & Torbjorn Jansson & Diti Oudendag & Alexander Gocht & David Verhoog, 2012. "Agricultural GHG emissions in the EU: an exploratory economic assessment of mitigation policy options," JRC Research Reports JRC69817, Joint Research Centre.
    6. Robert H. Beach & Benjamin J. DeAngelo & Steven Rose & Changsheng Li & William Salas & Stephen J. DelGrosso, 2008. "Mitigation potential and costs for global agricultural greenhouse gas emissions-super-1," Agricultural Economics, International Association of Agricultural Economists, vol. 38(2), pages 109-115, March.
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