Leonidas Ntziachristos ETC/ACM

1. An assessment of uncertainty in COPERT4 & managing differences arising from model development:from COPERTII to COPERT4 Leonidas Ntziachristos ETC/ACM Updated version of: Road transport emission inventory uncertainties – GHGs and APs,EEA, Copenhagen, 18 November 2010 http://www.eionet.europa.eu/events/transport%20uncertainties/

2. Agenda of the Nov. 18, 2010 meeting TFEIP Stockholm

3. Projected emission factors • Emission reductions for future vehicle technologies generally follow the rule: • Limitation: • Real-world behaviour does not (always) follow emission standards TFEIP Stockholm

4. Example: Euro V trucks NOx • Emission Level • EF over ES ratios TFEIP Stockholm

5. Impacts • Uncertainty of projection increases due to inability to predict real-world behaviour beforehand • Difficulties to meet targets may originate from such uncertainty in setting targets • Best example: NECD TFEIP Stockholm

6. Towards NECD: Current Assessment Source: Nitrogen oxide (NOx) distance-to-target for EEA member countries, EEA, Oct. 2010. TFEIP Stockholm

7. Responsible: Model or Regulation? • Model projects what regulations wished to achieve • Reality proves that regulations failed to achieve • Manufacturers followed “letter” not “spirit” of law! • Improvements required to regulations • Different driving profile? • Non-to-exceed approach? TFEIP Stockholm

8. Quantifying uncertainties • Use new knowledge • Models • Activity data • Compare with • Old models • Old activity data • Objective: Explain uncertainty due to model and activity data differences TFEIP Stockholm

9. Approach to quantify uncertainty: input data • RAINS activity and emission factor data used to set the NECD targets • Cost-effective Control of Acidification and Ground-Level Ozone. Part A: Methodology and Databases. Sixth Interim Report to the European Commission, IIASA 1998. • Actual excel files received by J. Cofala, Oct. 2010. • FLEETS/EC4MACS data • Updated datasets used by GAINS in the framework of LIFE EC4MACS • Based on original data by individual MSs • Four countries used as examples:DE, FR, IE, NL TFEIP Stockholm

10. Approach to quantify uncertainty: models • COPERT II (1997) • Used to provide removal efficiencies to RAINS • COPERT 4 v8.0 (Nov. 2010) • Most updated version, implementing HBEFA 3.1 HDV EFs TFEIP Stockholm

11. Runs executed (Germany) • Run 1: Original RAINS calculation • Run 2: COPERT 2 + RAINS Input • Run 3: COPERT 2 + EC4MACS Input • Run 4: COPERT 4 + RAINS Input • Run 5: COPERT 4 + EC4MACS Input TFEIP Stockholm

12. DE: Activity TFEIP Stockholm

13. DE: Technology penetration TFEIP Stockholm

14. 34% activity 75% EF DE: NOx Emissions TFEIP Stockholm

15. DE 2010: Technology responsibility TFEIP Stockholm

16. IE: Activity TFEIP Stockholm

17. 131% activity 64% EF IE: NOx Emissions TFEIP Stockholm

18. IE 2010: Technology responsibility TFEIP Stockholm

19. Summary • Differences between target and reality result from both emission factors and activity data • 65-75% higher emissions due to EFs • 19-131% higher emissions due to activity data • Emission factors • Practically all Euro 3 / III and later diesel EFs • Conventional/E1 GPC! • Activity data: • Misallocation of HD, LD diesel consumption • Relative increase of DPC consumption • Too fast scrappage of old vehicles assumed TFEIP Stockholm

20. More Info http://acm.eionet.europa.eu/reports/ETCACC_TP_2010_20_Copert2vsCopert4 TFEIP Stockholm