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Mitigation of Climate Change

Mitigation of Climate Change. IPCC Working Group III contribution to the Fourth Assessment Report. Bert Metz Co-chair IPCC WG III IUGG Conference, Perugia, Italy, July 5, 2007. Total GHG emissions. Between 1970 and 2004 global greenhouse gas emissions have increased by 70 %. 60.

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Mitigation of Climate Change

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  1. Mitigation of Climate Change IPCC Working Group III contribution to the Fourth Assessment Report Bert Metz Co-chair IPCC WG III IUGG Conference, Perugia, Italy, July 5, 2007

  2. Total GHG emissions Between 1970 and 2004 global greenhouse gas emissions have increased by 70 % 60 GtCO2-eq/yr 55 50 45 40 35 30 25 20 15 10 5 0 2004 1970 1980 1990 2000

  3. Carbon dioxide is the largest contributor

  4. With current climate change mitigation policies and related sustainable development practices, global GHG emissions will continue to grow over the next few decades • IPCC SRES scenarios: 25-90 % increase of GHG emissions in 2030 relative to 2000 GtCO2eq/yr 2030

  5. Economic mitigation potential could offset the projected growth of global emissions, or reduce emissions below current levels TOP-DOWN BOTTOM-UP Global economic potential in 2030 Note: estimates do not include non-technical options such as lifestyle changes

  6. What does US$ 50/ tCO2eq mean? • Crude oil: ~US$ 25/ barrel • Gasoline: ~12 ct/ litre (50 ct/gallon) • Electricity: • from coal fired plant: ~5 ct/kWh • from gas fired plant: ~1.5 ct/kWh

  7. All sectors and regions have the potential to contribute Note: estimates do not include non-technical options, such as lifestyle changes.

  8. Commercial energy supply mitigation technologies 2030 NOW

  9. Commercial transport mitigation technologies NOW 2030

  10. Commercial mitigation technologies in the building sector 2030 NOW

  11. Changes in lifestyle and behaviour patterns can contribute to climate change mitigation • Changes in occupant behaviour, cultural patterns and consumer choice in buildings. • Reduction of car usage and efficient driving style, in relation to urban planning and availability of public transport • Behaviour of staff in industrial organizations in light of reward systems

  12. What are the macro-economic costs in 2030? • Costs are global average for least cost appoaches from top-down models • Costs do not include co-benefits and avoided climate change damages [1] This is global GDP based market exchange rates. [2] The median and the 10th and 90th percentile range of the analyzed data are given. [3] The calculation of the reduction of the annual growth rate is based on the average reduction during the period till 2030 that would result in the indicated GDP decrease in 2030. [4] The number of studies that report GDP results is relatively small and they generally use low baselines.

  13. Illustration of cost numbers GDP GDP without mitigation 80% 77% GDP with stringent mitigation Time current ~1 year

  14. Examples of side-effects of climate mitigation

  15. The key question: can “dangerous anthropogenic climate change” be avoided? EU, Norway At 2 degrees global mean warming serious adaptation is required!

  16. The lower the stabilisation level the earlier global emissions have to go down Multigas and CO2 only studies combined

  17. Mitigation efforts over the next two to three decades will have a large impact on opportunities to achieve lower stabilization levels [1] The best estimate of climate sensitivity is 3ºC [WG 1 SPM]. [2] Note that global mean temperature at equilibrium is different from expected global mean temperature at the time of stabilization of GHG concentrations due to the inertia of the climate system. For the majority of scenarios assessed, stabilisation of GHG concentrations occurs between 2100 and 2150. [3] Ranges correspond to the 15th to 85th percentile of the post-TAR scenario distribution. CO2 emissions are shown so multi-gas scenarios can be compared with CO2-only scenarios.

  18. Technology • The range of stabilization levels can be achieved by • deployment of a portfolio of technologies that are currently available and • those that are expected to be commercialised in coming decades. • This assumes that appropriate and effective incentives are in place for development, acquisition, deployment and diffusion of technologies and for addressing related barriers 450 CO2-eq 650 CO2-eq 550 CO2-eq Other Sinks Nuclear, renewable CCS Fuel switch Non-CO2 Efficiency Biofuels

  19. The policy challenge • Many barriers for implementing low-cost mitigation measures • An effective carbon-price signal could realise significant mitigation potential in all sectors • Policies are essential to create a carbon price (direct or indirect) • Meaningful climate policy should lead to carbon prices of $50-100/tCO2eq by 2030

  20. Investments • Energy infrastructure investment decisions, (20 trillion US$ till 2030) will have long term impacts on GHG emissions. • The widespread diffusion of low-carbon technologies may take many decades, even if early investments in these technologies are made attractive. • Returning global energy-related CO2 emissions to 2005 levels by 2030 would require a large shift in the pattern of investment, although the net additional investment required ranges from negligible to 5-10% • It is often more cost-effective to invest in end-use energy efficiency improvement than in increasing energy supply

  21. The importance of technology policies • The lower the stabilization levels (550 ppm CO2-eq or lower) the greater the need for more efficient RD&D efforts and investment in new technologies during the next few decades • Government support is important for effective technology development, innovation and deployment through • financial contributions, • tax credits, • standard setting • market creation. • BUT, government funding for most energy research programmes has been declining for nearly two decades: now about half of 1980 level.

  22. Box 13.7: The range of the difference between emissions in 1990 and emission allowances in 2020/2050 for various GHG concentration levels for the Annex I and non-Annex I countries as a group1) Implications for international agreements

  23. Climate policy alone will not solve the climate change problem • Macro-economic policy: taxes, subsidies, other fiscal policies, structural adjustment • Trade policy: “embodied carbon”, removing barriers for low-carbon products, domestic energy sources • Energy security policy : efficient energy use, domestic energy sources (low-high carbon) • Access to modern energy: bioenergy, poverty tariffs • Air quality policy: clean fuel • Bank lending policies: lending for efficiency/ renewables, avoid lock-in into old technologies in developing countries • Insurance policy: Differentiated premiums, liability insurance exclusion, improved conditions for green products

  24. Development path with HIGH base emissions Development path does make a difference Development path with LOW emissions

  25. The Summary for Policy Makers , the Technical Summary and the full Report (subject to editing) can be downloaded fromwww.mnp.nl/ipccFurther information:IPCC Working Group III Technical Support Unit at the Netherlands Environmental Assessment Agency:ipcc3tsu@mnp.nl

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