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CAPRI

Common Agricultural Policy Regional Impact Analysis

Agriculturepartial equilibrium modelEnvironmentagricultureCAPimpact analysisclimate changegreenhouse gas

References

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Climate change impacts and adaptation in Europe 

Feyen, L., Ciscar Martinez, J., Gosling, S., Ibarreta Ruiz, D., Soria Ramirez, A., Dosio, A., Naumann, G., Russo, S., Formetta, G., Forzieri, G., Girardello, M., Spinoni, J., Mentaschi, L., Bisselink, B., Bernhard, J., Gelati, E., Adamovic, M., Guenther, S., De Roo, A., Cammalleri, C., Dottori, F., Bianchi, A., Alfieri, L., Vousdoukas, M., Mongelli, I., Hinkel, J., Ward, P., Gomes Da Costa, H., De Rigo, D., Liberta`, G., Durrant, T., San-Miguel-Ayanz, J., Barredo Cano, J., Mauri, A., Caudullo, G., Ceccherini, G., Beck, P., Cescatti, A., Hristov, J., Toreti, A., Perez Dominguez, I., Dentener, F., Fellmann, T., Elleby, C., Ceglar, A., Fumagalli, D., Niemeyer, S., Cerrani, I., Panarello, L., Bratu, M., Després, J., Szewczyk, W., Matei, N., Mulholland, E. and Olariaga-Guardiola, M., Climate change impacts and adaptation in Europe, EUR 30180 EN, Publications Office of the European Union, Luxembourg, 2020, ISBN 978-92-76-18123-1 (online), doi:10.2760/171121 (online), JRC119178.

Economic assessment of GHG mitigation policy options for EU agriculture 

Perez Dominguez, I., Fellmann, T., Witzke, H., Weiss, F., Hristov, J., Himics, M., Barreiro Hurle, J., Gomez Barbero, M. and Leip, A., Economic assessment of GHG mitigation policy options for EU agriculture, EUR 30164 EN, Publications Office of the European Union, Luxembourg, 2020, ISBN 978-92-76-17854-5 (online),978-92-76-17855-2 (print), doi:10.2760/4668 (online),10.2760/552529 (print), JRC120355.

An economic assessment of GHG mitigation policy options for EU agriculture (EcAMPA 2) 

Lead by: AGRI, run by : JRC.D.4
The model endogenously calculates greenhouse gas (GHG) emissions for the major non-CO2 sources in agriculture and, therefore, can analyse the effects of changes in policies and the market environment on GHG emissions.

EU reference scenario 2016 Energy, transport and GHG emissions : trends to 2050 

Lead by: ENER,MOVE,CLIMA, run by : University of Bonn
The model takes inputs from GEM-E3, PRIMES and PRIMES Biomass model, provides outputs to GAINS, and exchanges information with GLOBIOM on livestock, crops, and forestry as well as LULUCF effects.

Greenhouse gas emissions from the EU livestock sector: A life cycle assessment carried out with the CAPRI model 

Weiss F, Leip A. Greenhouse gas emissions from the EU livestock sector: A life cycle assessment carried out with the CAPRI model. AGRICULTURE ECOSYSTEMS and ENVIRONMENT 149; 2012. p. 124-134. JRC68859

Potential EU-Mercosur Free Trade Agreement: Impact Assessment 

Burrell A, Ferrari E, Gonzalez Mellado A, Himics M, Michalek J, Shrestha S, Van Doorslaer B, authors Burrell A, editor. Potential EU-Mercosur Free Trade Agreement: Impact Assessment. EUR 25011 EN. Luxembourg (Luxembourg): Publications Office of the European Union; 2011. JRC67394

peer review for model validation

Short- and long-term warming effects of methane may affect the cost-effectiveness of mitigation policies and benefits of low-meat diets 

Pérez-Domínguez, I., del Prado, A., Mittenzwei, K., Hristov, J., Frank, S., Tabeau, A., Witzke, P., Havlik, P., van Meijl, H., Lynch, J., Stehfest, E., Pardo, G., Barreiro-Hurle, J., Koopman, J. F. L., & Sanz-Sánchez, M. J. (2021). Short- and long-term warming effects of methane may affect the cost-effectiveness of mitigation policies and benefits of low-meat diets. Nature Food, 2(12), 970–980. https://doi.org/10.1038/s43016-021-00385-8

Greenhouse gas mitigation technologies in agriculture: Regional circumstances and interactions determine cost-effectiveness 

Fellmann, T., Domínguez, I. P., Witzke, P., Weiss, F., Hristov, J., Barreiro-Hurle, J., Leip, A., & Himics, M. (2021). Greenhouse gas mitigation technologies in agriculture: Regional circumstances and interactions determine cost-effectiveness. Journal of Cleaner Production, 317, 128406. https://doi.org/10.1016/j.jclepro.2021.128406

Reuse of treated water in European agriculture: Potential to address water scarcity under climate change 

Hristov, J., Barreiro-Hurle, J., Salputra, G., Blanco, M., & Witzke, P. (2021). Reuse of treated water in European agriculture: Potential to address water scarcity under climate change. Agricultural Water Management, 251, 106872. https://doi.org/10.1016/j.agwat.2021.106872

Setting Climate Action as the Priority for the Common Agricultural Policy: A Simulation Experiment 

Himics, M., Fellmann, T., & Barreiro‐Hurle, J. (2019). Setting Climate Action as the Priority for the Common Agricultural Policy: A Simulation Experiment. Journal of Agricultural Economics, 71(1), 50–69. Portico. https://doi.org/10.1111/1477-9552.12339

Does the current trade liberalization agenda contribute to greenhouse gas emission mitigation in agriculture? 

Himics, M., Fellmann, T., Barreiro Hurle, J., Witzke, H., Perez Dominguez, I., Jansson, T. and Weiss, F., Does the current trade liberalization agenda contribute to greenhouse gas emission mitigation in agriculture, FOOD POLICY, ISSN 0306-9192, 76, 2018, p. 120-129, JRC110846.

Risk of increased food insecurity under stringent global climate change mitigation policy 

Hasegawa, T., Fujimori, S., Havlik, P., Valin, H., Bodirsky, B., Doelman, J., Fellmann, T., Kyle, P., Koopman, J., Lotze-Campen, H., Mason-D`croz, D., Ochi, Y., Perez Dominguez, I., Stehfest, E., Sulser, T., Tabeau, A., Takahashi, K., Takakura, J., Van Meijl, H., Van Zeist, W., Wiebe, K. and Witzke, H., Risk of increased food insecurity under stringent global climate change mitigation policy, NATURE CLIMATE CHANGE, ISSN 1758-678X, 8, 2018, p. 699-703, JRC110841.

Comparing impacts of climate change and mitigation on global agriculture by 2050 

Van Meijl, H., Havlik, P., Lotze-Campen, H., Stehfest, E., Witzke, H., Perez Dominguez, I., Bodirsky, B., Van Dijk, M., Doelman, J., Fellmann, T., Humpenoeder, F., Levin-Koopman, J., Müller, C., Popp, A., Tabeau, A., Valin, H. and Van Zeist, W., Comparing impacts of climate change and mitigation on global agriculture by 2050, ENVIRONMENTAL RESEARCH LETTERS, ISSN 1748-9326, 13, 2018, p. 060421, JRC110838.

Agricultural non-CO2 emission reduction potential in the context of the 1.5 °C target 

Frank, S., Havlík, P., Stehfest, E., van Meijl, H., Witzke, P., Pérez-Domínguez, I., … Valin, H. (2018). Agricultural non-CO2 emission reduction potential in the context of the 1.5 °C target. Nature Climate Change, 9(1), 66–72. doi:10.1038/s41558-018-0358-8

Major challenges of integrating agriculture into climate change mitigation policy frameworks 

Fellmann, T., Witzke, P., Weiss, F., Van Doorslaer, B., Drabik, D., Huck, I., Salputra, G., Jansson, T., & Leip, A. (2017). Major challenges of integrating agriculture into climate change mitigation policy frameworks. Mitigation and Adaptation Strategies for Global Change, 23(3), 451–468. https://doi.org/10.1007/s11027-017-9743-2

model documentation

No references in this category

Policy reform and agricultural land abandonment in the EU 

Renwick, A., Jansson, T., Verburg, P. H., Revoredo-Giha, C., Britz, W., Gocht, A., & McCracken, D. (2013). Policy reform and agricultural land abandonment in the EU. Land Use Policy, 30(1), 446–457. doi:10.1016/j.landusepol.2012.04.005

Exploring the feasibility of integrating water issues into the CAPRI model 

Blanco Fonseca M, Van Doorslaer B, Britz W, Witzke H. Exploring the feasibility of integrating water issues into the CAPRI model. EUR 25649. Luxembourg (Luxembourg): Publications Office of the European Union; 2012. JRC77058