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sector:energy:fuel_combustion:transport:civil_aviation:start [2021/04/08 08:37] kotzullasector:energy:fuel_combustion:transport:civil_aviation:start [2021/12/15 20:00] (current) – external edit 127.0.0.1
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 ==== Activity Data ==== ==== Activity Data ====
  
-Emissions estimation is mainly based on consumption data for jet kerosene and aviation gasoline as provided in the national Energy Balances (AGEB, 2020) [(AGEB2020)]. For very recent years with no AGEB data available (Normally the last year of the period reported.) data provided by the Federal Office of Economics and Export Control (BAFA) is being used.+Emissions estimation is mainly based on consumption data for jet kerosene and aviation gasoline as provided in the national Energy Balances (AGEB, 2020) [(AGEB2020)]. For very recent years with no AGEB data available (Normally the last year of the period reported.) data provided by the Federal Office of Economics and Export Control (BAFA) [(BAFA2020)] is being used.
  
 Table 1: Sources for 1.A.3.a activity data Table 1: Sources for 1.A.3.a activity data
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 Within the IPCC EF data base, there are no default data provided for emissions of particulate matter (TSP, PM<sub>10</sub>, and PM<sub>2.5</sub>). Therefore, the EF for dust (**T**otal **S**uspended **P**articulate Matter – **TSP**) are taken over from Corinair (2006) [(CORINAIR2006)], giving specific values for an average fleet and for the two flight stages in table 8.2: For national flights 0.7 kg TSP/LTO and 0.2 kg TSP/t kerosene and 0.15 kg TSP/LTO and 0.2 kg TSP/t kerosene for international flights. Following this table, a kerosene consumption per LTO cycle of 825 kg for national and 1,617 kg for international flights have been assumed and the EF for the LTO stage have been estimated. Within the IPCC EF data base, there are no default data provided for emissions of particulate matter (TSP, PM<sub>10</sub>, and PM<sub>2.5</sub>). Therefore, the EF for dust (**T**otal **S**uspended **P**articulate Matter – **TSP**) are taken over from Corinair (2006) [(CORINAIR2006)], giving specific values for an average fleet and for the two flight stages in table 8.2: For national flights 0.7 kg TSP/LTO and 0.2 kg TSP/t kerosene and 0.15 kg TSP/LTO and 0.2 kg TSP/t kerosene for international flights. Following this table, a kerosene consumption per LTO cycle of 825 kg for national and 1,617 kg for international flights have been assumed and the EF for the LTO stage have been estimated.
  
-The EF for **water vapor (H<sub>2</sub>O)** provided by Eurocontrol (2004) is about 1,230g H<sub>2</sub>O / kg kerosene, whereas in Corinair (2006) [(CORINAIR2006)] 1,237g H<sub>2</sub>O /kg is assumed. Based on the stoichiometric assumptions mentioned above a EF(CO<sub>2</sub>) of 1.24 kg H,,2,,O/kg can be derived. To reduce the number of sources for EF, here, the Corinair value has been used for both flight stages and for both national and international flights.+The EF for **water vapor (H<sub>2</sub>O)** provided by Eurocontrol (2004) is about 1,230g H<sub>2</sub>O / kg kerosene, whereas in Corinair (2006) [(CORINAIR2006)] 1,237g H<sub>2</sub>O /kg is assumed. Based on the stoichiometric assumptions mentioned above a EF(CO<sub>2</sub>) of 1.24 kg H<sub>2</sub>O/kg can be derived. To reduce the number of sources for EF, here, the Corinair value has been used for both flight stages and for both national and international flights.
  
 As for **polycyclic aromatic hydrocarbons** (PAH), tier1 EF from (EMEP/EEA, 2019) [(EMEPEEA2019)] have been apllied here. As the EMEP guidebook does not provide original EF for jet kerosene, values provided for gasoline in road transport have been used here as a proxy and will be replaced by more appropriate data as soon as this is available. As for **polycyclic aromatic hydrocarbons** (PAH), tier1 EF from (EMEP/EEA, 2019) [(EMEPEEA2019)] have been apllied here. As the EMEP guidebook does not provide original EF for jet kerosene, values provided for gasoline in road transport have been used here as a proxy and will be replaced by more appropriate data as soon as this is available.
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 > **NOTE:** For the country-specific emission factors applied for particulate matter, no clear indication is available, whether or not condensables are included.   > **NOTE:** For the country-specific emission factors applied for particulate matter, no clear indication is available, whether or not condensables are included.  
  
-> For information on the **emission factors for heavy-metal and POP exhaust emissions**, please refer to [[[ appendix2.3-HM-from-mobile-sources | Appendix 2.3 - Heavy Metal (HM) exhaust emissions from mobile sources]]] and [[[ appendix2.4-POPs-from-mobile-sources | Appendix 2.4 - Persistent Organic Pollutant (POP) exhaust emissions from mobile sources ]]].+> For information on the **emission factors for heavy-metal and POP exhaust emissions**, please refer to Appendix 2.3 - Heavy Metal (HM) exhaust emissions from mobile sources and Appendix 2.4 - Persistent Organic Pollutant (POP) exhaust emissions from mobile sources.
  
 =====Recalculations===== =====Recalculations=====
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 Information on uncertainties is provided here with most data representing expert judgement from the research project mentioned above. Information on uncertainties is provided here with most data representing expert judgement from the research project mentioned above.
  
-For estimating uncertainties, the partial uncertainties (U,,1,, to U,,n,,) of the components incorporated in emission calculations have to be quantified. +For estimating uncertainties, the partial uncertainties (U<sub>1</sub> to U<sub>n</sub>) of the components incorporated in emission calculations have to be quantified. 
-By additive linking of the squared partial uncertainties the overall uncertainty (U,,total,,) can then be estimated (IPCC, 2000) [(IPCC2000)].+By additive linking of the squared partial uncertainties the overall uncertainty (U<sub>total</sub>) can then be estimated (IPCC, 2000) [(IPCC2000)].
  
 The uncertainties given here have been evaluated for all time series and flight stages as average values. The uncertainties given here have been evaluated for all time series and flight stages as average values.
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 For the years 1990 to 2002 data is based upon estimations carried out within TREMOD AV which themselves are based on data from the Federal Statistical Office and EF from the EMEP-EEA data base. For 2003 to 2011 data from Eurocontrol are being used, that are calculated within ANCAT. Comparing results from the ANCAT model with actual consumption data show aberrations of ±12 %. Here, data calculated with AEM 3 model would have an uncertainty of only 3 to 5 % (EUROCONTROL 2006) [(EUROCONTROL2006)]. For the years 1990 to 2002 data is based upon estimations carried out within TREMOD AV which themselves are based on data from the Federal Statistical Office and EF from the EMEP-EEA data base. For 2003 to 2011 data from Eurocontrol are being used, that are calculated within ANCAT. Comparing results from the ANCAT model with actual consumption data show aberrations of ±12 %. Here, data calculated with AEM 3 model would have an uncertainty of only 3 to 5 % (EUROCONTROL 2006) [(EUROCONTROL2006)].
  
-The image below shows the partial uncertainties and correlations used for uncertainty estimations carried out during the research project. Mouseclick to enlarge! +As no uncertainty estimates were carried out for ammonia and particulate matter within the above-mentioned project, values from the PAREST research project mentioned for most over mobile sources were used. Here, the final report has not yet been published.
-[[gallery size="medium"]] +
-: Uncertainties.png +
-[[/gallery]] +
- +
-As no uncertainty estimates were carried out for NH,,3,, and particulate matter within the above-mentioned project, values from the PAREST research project mentioned for most over mobile sources were used. Here, the final report has not yet been published.+
  
  
 ===== FAQs ===== ===== FAQs =====
  
-**//Whereby does the party justify the adding-up of the two amounts given in BAFA table 7j as deliveries 'An die Luftfahrt' and 'An Sonstige' ?//**+**Whereby does the party justify the adding-up of the two amounts given in BAFA table 7j as deliveries 'An die Luftfahrt' and 'An Sonstige' ?**
  
 For mineral oils, German National Energy Balances (NEBs) - amongst other sources - are based on BAFA data on the amounts delivered to different sectors. A comparison with consumption data from AGEB and BAFA shows that data from NEB line 76 /63: 'Luftverkehr' equates to the amount added from both columns in BAFA table 7j. For mineral oils, German National Energy Balances (NEBs) - amongst other sources - are based on BAFA data on the amounts delivered to different sectors. A comparison with consumption data from AGEB and BAFA shows that data from NEB line 76 /63: 'Luftverkehr' equates to the amount added from both columns in BAFA table 7j.
  
-**//Why is there no aviation gasoline reported under 1.A.3.a i - International Civil Aviation?//**+**On which basis does the party estimate the reported lead emissions from aviation gasoline?**
  
-Due to the lack of further information, the party assumes that aviation gasoline is only being used for domestic civil aviation. - Furthermore, the party also assumes that the use of aviation gasoline in domestic civil aviation takes place below 3,000 feet only - and therewith only within the LTO-range (1.A.3.a ii (i)).+assumption by partyaviation gasoline = AvGas 100 LL 
 +(AvGas 100 LL is the predominant sort of aviation gasoline in Western Europe)1 
 +lead content of AvGas 100 LL: 0.56 g lead/liter (as tetra ethyl lead)2
  
 +The applied procedure is similar to the one used for calculating lead emissions from leaded gasoline used in road transport. (There, in contrast to aviation gasoline, the lead content constantly declined resulting in a ban of leaded gasoline in 1997.)
 +
 +**On which basis does the party estimate the reported TSP emissions from aviation gasoline?**
 +
 +The TSP emissions calculated depend directly on the reported lead emissions: The emission factor for TSP is 1.6 times the emission factor used for lead: EF(TSP) = 1.6 x EF(Pb).
 +The applied procedure is similar to the one used for calculating TSP emissions from leaded gasoline used in road transport.
 +
 +[(AGEB2020>AGEB, 2020: Working Group on Energy Balances (Arbeitsgemeinschaft Energiebilanzen (Hrsg.), AGEB): Energiebilanz für die Bundesrepublik Deutschland; URL: http://www.ag-energiebilanzen.de/7-0-Bilanzen-1990-2018.html, (Aufruf: 29.11.2020), Köln & Berlin, 2020.)]
 +[(BAFA2020>BAFA, 2020: Federal Office of Economics and Export Control (Bundesamt für Wirtschaft und Ausfuhrkontrolle, BAFA): Amtliche Mineralöldaten für die Bundesrepublik Deutschland;
 +URL: https://www.bafa.de/SharedDocs/Downloads/DE/Energie/Mineraloel/moel_amtliche_daten_2018_dezember.html, Eschborn, 2020.)]
 [(KNOERR2010> Knörr, W., Schacht, A., & Gores, S. (2010): Entwicklung eines eigenständigen Modells zur Berechnung des Flugverkehrs (TREMOD-AV) : Endbericht. Endbericht zum F+E-Vorhaben 360 16 029, URL: https://www.umweltbundesamt.de/publikationen/entwicklung-eines-modells-zur-berechnung; Berlin & Heidelberg, 2012.)] [(KNOERR2010> Knörr, W., Schacht, A., & Gores, S. (2010): Entwicklung eines eigenständigen Modells zur Berechnung des Flugverkehrs (TREMOD-AV) : Endbericht. Endbericht zum F+E-Vorhaben 360 16 029, URL: https://www.umweltbundesamt.de/publikationen/entwicklung-eines-modells-zur-berechnung; Berlin & Heidelberg, 2012.)]
 [(KNOERR2020c> Knörr et al. (2020c): Knörr, W., Schacht, A., & Gores, S.: TREMOD Aviation (TREMOD AV) 2018 - Revision des Modells zur Berechnung des Flugverkehrs (TREMOD-AV). Heidelberg, Berlin: Ifeu Institut für Energie- und Umweltforschung Heidelberg GmbH & Öko-Institut e.V., Berlin & Heidelberg, 2020.)] [(KNOERR2020c> Knörr et al. (2020c): Knörr, W., Schacht, A., & Gores, S.: TREMOD Aviation (TREMOD AV) 2018 - Revision des Modells zur Berechnung des Flugverkehrs (TREMOD-AV). Heidelberg, Berlin: Ifeu Institut für Energie- und Umweltforschung Heidelberg GmbH & Öko-Institut e.V., Berlin & Heidelberg, 2020.)]
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 [(IPCC2000> IPCC, 2000: Intergovernmental Panel on Climate Change, Good Practice Guidance and Uncertainty Management in National Greenhouse Gas Inventories, IPCC Secretariat, 16th Session, Montreal, 1-8 May 2000, URL: http://www.ipcc-nggip.iges.or.jp/public/gp/english/ )] [(IPCC2000> IPCC, 2000: Intergovernmental Panel on Climate Change, Good Practice Guidance and Uncertainty Management in National Greenhouse Gas Inventories, IPCC Secretariat, 16th Session, Montreal, 1-8 May 2000, URL: http://www.ipcc-nggip.iges.or.jp/public/gp/english/ )]
 [(EUROCONTROL2006> EUROCONTROL, 2006 – The Advanced Emission Model (AEM3) - Validation Report, Jelinek, F., Carlier, S., Smith, J., EEC Report EEC/SEE/2004/004, Brüssel 2004 URL: http://www.eurocontrol.int/eec/public/standard_page/DOC_Report_2004_016.html http://www.eurocontrol.int/eec/public/standard_page/DOC_Report_2006_030.html )] [(EUROCONTROL2006> EUROCONTROL, 2006 – The Advanced Emission Model (AEM3) - Validation Report, Jelinek, F., Carlier, S., Smith, J., EEC Report EEC/SEE/2004/004, Brüssel 2004 URL: http://www.eurocontrol.int/eec/public/standard_page/DOC_Report_2004_016.html http://www.eurocontrol.int/eec/public/standard_page/DOC_Report_2006_030.html )]
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