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dc.contributor.authorIerland EC van
dc.contributor.authorIgnaciuk A
dc.contributor.authorKroeze C
dc.contributor.authorBrink C
dc.contributor.authorSchmieman E
dc.contributor.authorBuiltjes P
dc.contributor.authorRoemer M
dc.contributor.authorMayerhofer P
dc.date.accessioned2012-12-12T18:59:50Z
dc.date.available2012-12-12T18:59:50Z
dc.date.issued2002-02-27
dc.identifier410200105
dc.identifier.isbn9058510867
dc.identifier.urihttp://hdl.handle.net/10029/259737
dc.description.abstractAbstract niet beschikbaar
dc.description.abstractThis project focuses on the interactions of climate change, acidification, eutrophication, tropospheric ozone, stratospheric ozone and some other air pollutants (like soot). The following research questions have been addressed: (i) Which interactions exist between acidification, tropospheric ozone formation, climate change and stratospheric ozone depletion? (ii) How can these interactions be analysed either by means of existing models, or by combining parts of these models, or by new model structures focusing on these interactions? (iii) Which data is required at the appropriate spatial and temporal scales for these themes, and how can these different scales be integrated? (iv) Which information is already available in existing emissions inventories and existing models? For a combined analysis of climate changes and transboundary air pollution, it is proposed to first decouple climate change calculations from air pollution calculations in an analysis at the global level, in order to determine emission reduction targets for greenhouse gases for Europe. For this purpose, calculations could first be performed with MERGE or ECHAM for climate change in order to establish emission targets for Europe. Next, the optimized emission levels (and of course also the calculated concentration fields and changed meteorological conditions) should be used as one of the restrictions in an optimisation analysis at the European level, using a newly developed model, based on elements of the RAINS model and the more detailed LOTOS system for transboundary air pollution. Subsequently with this model optimisation runs should be performed to calculate optimal emission reduction strategies for transboundary air pollution and emissions of greenhouse gases, considering the interactions as identified in this study.
dc.description.sponsorshipSG-NOP
dc.format.extent131 p
dc.language.isoen
dc.publisherWageningen University
dc.publisherTNO-MEP
dc.publisherApeldoorn
dc.relation.ispartofGlobal Change NOP-NRP report 410200105
dc.relation.urlhttp://www.rivm.nl/bibliotheek/rapporten/410200105.html
dc.subjectMILIEU-ANALYSEnl
dc.subjectklimaatveranderingnl
dc.subjectverzuringnl
dc.subjectozonnl
dc.subjectmodellenonderzoeknl
dc.subjectclimatic changesen
dc.subjectacidificationen
dc.subjectozoneen
dc.subjectmodellingen
dc.titleApproaches to analyse interactions of climate change, acidification and ozoneen
dc.title.alternativeHoe interacties tussen klimaatverandering, verzuring en ozon te analyseren?nl
dc.typeOnderzoeksrapport
dc.contributor.departmentNOP
dc.date.updated2012-12-12T18:59:50Z
html.description.abstractAbstract niet beschikbaar
html.description.abstractThis project focuses on the interactions of climate change, acidification, eutrophication, tropospheric ozone, stratospheric ozone and some other air pollutants (like soot). The following research questions have been addressed: (i) Which interactions exist between acidification, tropospheric ozone formation, climate change and stratospheric ozone depletion? (ii) How can these interactions be analysed either by means of existing models, or by combining parts of these models, or by new model structures focusing on these interactions? (iii) Which data is required at the appropriate spatial and temporal scales for these themes, and how can these different scales be integrated? (iv) Which information is already available in existing emissions inventories and existing models? For a combined analysis of climate changes and transboundary air pollution, it is proposed to first decouple climate change calculations from air pollution calculations in an analysis at the global level, in order to determine emission reduction targets for greenhouse gases for Europe. For this purpose, calculations could first be performed with MERGE or ECHAM for climate change in order to establish emission targets for Europe. Next, the optimized emission levels (and of course also the calculated concentration fields and changed meteorological conditions) should be used as one of the restrictions in an optimisation analysis at the European level, using a newly developed model, based on elements of the RAINS model and the more detailed LOTOS system for transboundary air pollution. Subsequently with this model optimisation runs should be performed to calculate optimal emission reduction strategies for transboundary air pollution and emissions of greenhouse gases, considering the interactions as identified in this study.


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