Post on 12-Jan-2016
The Science and Politics of Climate Change
Fresh from the Hague
Robert T. WatsonChief Scientist & Director, ESSD
Chairman, Intergovernmental Panel on Climate Change
December 6, 2000 - MC 12 Floor Gallery - 1:00 p.m.
Annual Temperature Trends, (°C / century) 1901-1999
Source: P. Jones, et. al. 2000.
Ch
ang
e in
tem
per
atu
re (
°C)
1860 1880 1900 1920 1940 1960 1980 2000
1.0
0.8
0.6
0.4
0.2
0.0
–0.2
Global Temperature ObservationsAnnual averages plus long-term trends, to July 1999
The Met.Office Hadley Centre for Climate Prediction and Research
Millennial Northern Hemisphere (NH)Temperature Reconstruction (blue) and Instrumental Data (red) from
AD 1000-1999
Source: Mann et al. 1999.
Precipitation Trends (%)per Decade (1900-1994)
Green • = increasing / Brown • = decreasing
Concentration of Carbon Dioxide and Methane Have Risen Greatly Since Pre-Industrial Times
Carbon dioxide: 33% rise Methane: 100% rise
The MetOffice. Hadley Center for Climate Prediction and Research.
Comparison of Temperature Observationsand Model Simulations
Source: Tett, et.al., 1999 and Stott, et.al., 2000.
Percent of the Continental U.S. with A MuchAbove Normal Proportion of Total Annual Precipitation From 1-day Extreme Events
(more than 2 inches or 50.8mm)
Source: Karl, et.al. 1996.
Schematic Illustration of SRES Scenarios
Scenarios
• Population (billion) 5.3 7.0 - 15.1
• World GDP (1012 1990US$/yr) 21 235 - 550
• Per capita income ratio: 16.1 1.5 - 4.2developed countries to developing countries
• Final energy intensity (106J/US$)a 16.7 1.4 - 5.9
• Primary energy (1018 J/US$) 351 514 - 2226
• Share of coal in primary energy (%)a 24 1 - 53
• Share of zero carbon in primary energy (%)a 18 28 - 35
1990 2100
a 1990 values include non-commercial energy consistent with IPCC WGII SAR (Energy Primer) but with SRES accounting conventions. Note that ASF, MiniCam, and IMAGE scenarios do not consider non-commercial renewable energy. Hence, these scenarios report lower energy use.
0
2
4
6
8
10
1900 1950 2000 2050 2100
Glo
bal C
arbo
n D
ioxi
de E
mis
sion
sSR
ES
Scen
ario
s an
d D
atab
ase
Ran
ge(in
dex,
199
0=1)
IS92 range
A1, B2
A2
B1
Median
5%
95%
1990 range(all scenarios)
Maximum in Database
Minimum in Database
Total database range
Non
-inte
rven
tion
Non
-cla
ssifi
ed
Inte
rven
tion
Global CO2 Emissions from Energy & Industry
Source: IPCC. 2000. Emissions Scenarios. Working Group III. Cambridge.
0
50
100
150
200
250
Maximum in database
Minimum in database
Glo
bal S
ulfu
r D
ioxi
de E
mis
sion
s(M
tS)
1930 1960 2020 2050 2100
1990 range
IS92
A2
B1
Sul
fur
- no
n-co
ntro
l, an
d no
n-cl
assi
fied
sce
nari
os
Sul
fur
- co
ntro
l
B2
20801990
Total database range
Range of sulfur-controlscenarios in the database
A1
Global Anthropogenic SO2 Emissions (MtS)
Source: IPCC. 2000. Emissions Scenarios. Working Group III. Cambridge.
Projected Change in Global Mean Surface Temperature from Models using
the SRES Emissions Scenarios
Year
Te
mp
e ra
ture
Ch
ang
e (
º C)
5
4
3
2
1
0
6
SAR
Projected Changes in Annual Temperatures for the 2050s
The projected change in annual temperatures for the 2050s compared with the present day, when the climate model is driven with an increase in greenhouse gas concentrations equivalent to about a 1% increase per year in CO2. The Met Office. Hadley Centre for Climate Prediction and Research.
Projected Changes in Annual Precipitation for the 2050s
The projected change in annual precipitation for the 2050s compared with the present day, when the climate model is driven with an increase in greenhouse gas concentrations equivalent to about a 1% increase per year in CO2. The Met Office. Hadley Centre for Climate Prediction and Research.
The 1997/98 El Niño Strongest on Record*
*As shown by changes in sea-surface temperature (relative to the 1961-1990 average) for the eastern tropical Pacific off Peru.
El Niño years
La Niña years
Northern Hemisphere Winter
Potential Climate Change Impacts
Percentage change in 30-year average annual runoff by the 2080s.University of Southampton.
Annual Runoff
Crop Yield Change
Percentage change in average crop yields for the climate change scenario. Effects of CO2 are taken into account. Crops modeled are: wheat, maize and rice.
Jackson Institute, University College London / Goddard Institute for Space Studies / International Institute for Applied Systems Analysis
97/1091 16
Climate Change and Ecological Systems
• Biological systems have already been affected by changes in climate at the regional scale
• The structure and functioning of ecological systems will be altered and the biological diversity will decrease forests, especially Boreal forests are vulnerable due
to changes in disturbance regimes (pests and fires) coral reefs are threatened by increases in
temperature the current terrestrial uptake of carbon will likely
diminish over time and forest systems may even become a source of carbon
Vector (insect)-borne Diseases
Source: Modified WHO, as cited in Stone (1995).
Disease Vector
Populationat risk
(millions) Present distribution
Likelihood ofaltered
distributionwith warming
Malaria mosquito 2,100 (sub)tropics
Schistosomiasis water snail 600 (sub)tropics Filariasis mosquito 900 (sub)tropics Onchocerciasis (river blindness)
black fly 90 Africa/Latin America
African trypanosomiasis (sleeping sickness)
tsetse fly 50 tropical Africa
Dengue mosquito unavailable tropics Yellow fever mosquito unavailable tropical South
America & Africa
Likely Very likely
People at Risk from a 44 cm Sea-level Rise by the 2080s
Assuming 1990s Level of Flood Protection
Source: R. Nicholls, Middlesex University in the U.K. Meteorological Office. 1997. Climate Change and Its Impacts: A Global Perspective.
Sea Level Rise CommitmentThermal expansion and land ice melt
after an initial 1% increase in CO2 for 70 years
The Met Office. Hadley Centre for Climate Prediction and Research.
Co-Benefits - Adaptation
• Many sectors (e.g., water resources and agriculture) are vulnerable to natural climate variability, e.g., floods and droughts associated with ENSO events
• Identify technologies, practices and policies that can reduce the vulnerability of sectors to natural climate variability and can increase resilience to long-term climate change incorporate modern scientific forecasts of ENSO events into
sector management decisions integrated multi-sector watershed management and
appropriate water pricing policies elimination of inappropriate agricultural subsidies infrastructure design (e.g., buildings, bridges, roads)
50%
55%
60%
65%
70%
75%
80%
85%
90%
95%
100%
105%
110%
115%
120%
125%
130%
1990 1995 2000 2005 2010
Evo
lutio
n in
%
Parties' projections
SRES A1F1
SRES A1T
SRES A1B
SRES A2
SRES B1
SRES B2
OECD
IEA
US source LG
US source REF
US source HG
EU source
Average
Annex II
Annex I
EIT
Percentage Change in Emissionsfrom 1990 to 2010
Energy Emission Pathways and Stabilization Concentrations
Source: IPCC. 1995. Second Assessment Report. Working Group I. Cambridge.
Mitigation Options• Supply Side
Fuel switching (coal to oil to gas) Increased power plant efficiency (30% to ~60%) Renewables (biomass, solar, wind, hydro, etc.) Carbon dioxide sequestration Nuclear power
• Demand Side Transportation Commercial and residential buildings Industry
• Land-Use, Land-Use Change and Forestry Afforestation, Reforestation and slowing Deforestation Improved Forest, Cropland and Rangeland Management Agroforestry
• Waste Management and Reduced Halocarbon Emissions
Policy Instruments• Policies, which may need regional or international
agreement, include: Energy pricing strategies and taxes Removing subsidies that increase GHG emissions Internalizing environmental extranalities Tradable emissions permits--domestic and global Voluntary programs Regulatory programs including energy-efficiency standards Incentives for use of new technologies during market build-up Education and training such as product advisories and labels
• Accelerated development of technologies as well as understanding the barriers to diffusion into the marketplace requires intensified R&D by governments and the private sector
CarbonTrading
JI
MoreRenewables
MoreGEF
CleanTechnology
CleanFuel
EconomicInstruments
EnvironmentalStandards
RegionalAgreements
Sector Reform
Energy Efficiency
Rural Energy
InternalizingGlobal Externalities(supporting the post-Kyoto process)
Local/RegionalPollutionAbatement(to be strengthened)
Win-Win(in place)
Fuel For Thought: Strategy for The Year 2000
Co-Benefits - Mitigation• Co-benefits can lower the cost of climate change
mitigation• Identify technologies, practices and policies that can
simultaneously address local and regional environmental issues and climate changeenergy sector
• indoor and outdoor air quality• regional acid deposition
transportation sector• outdoor air pollution• traffic congestion
agriculture and forestry• soil fertility• biodiversity and related ecological goods and services
Pollution in Selected Cities (TSP)
Source: OECD Environmental data 1995; WRI China tables 1995; Central Pollution Control Board, Delhi. “Ambient Air Quality Status and Statistics, 1993 and 1994”; Urban Air Pollution in Megacities of the World, WHO/UNEP, 1992; EPA, AIRS database.
Health Costs (TSP in China)
Source: Clear Water, Blue Skies; China’s Environment in the New Century, World Bank, 1997.
Surprise
Geoth.
Solar
Biomass
Wind
Nuclear
Hydro
Gas
Oil & NGL
Coal
Trad Bio.0
500
1000
1500
1860 1880 1900 1920 1940 1960 1980 2000 2020 2040 2060
exajoules
Energy SupplySustained Growth Scenario
Source: Shell International Limited.
Key Conclusions
• The Earth’s climate is changing - temperatures and sea level are increasing, rainfall patterns are changing, glaciers are retreating, Arctic sea ice is thinning
• Human activities are changing the atmospheric concentrations of greenhouse gases
• The weight of scientific evidence suggests that human activities, are at least in part, the cause of the observed changes in climate
• The Earth’s mean annual surface temperature is projected to increase by about 1.5 to 6.0 degrees centigrade between 1990 and 2100, with land areas warming more than the oceans - precipitation patterns will change - sea level projected to rise about 50 cm (15-95 cm) by 2100
Key Conclusions
• Projected changes in climate will affect: water resources, especially in arid and semi-
arid lands agricultural productivity, especially in the
tropics and sub-tropics the structure and functioning, hence the goods
and services, of ecological systems human settlements due to sea level rise human health, e.g, vector-borne diseases
Key Conclusions
• A change in the Earth’s climate is inevitable
• The magnitude and rate of climate change will depend upon the adoption of policies, practices and technologies that influence greenhouse gas emissions
• Adaptation strategies can be adopted to reduce the vulnerability of socio-economic systems, ecological systems and human health to today’s climate variability and long-term human-induced climate change
Key Issues at COP-6
While there were significant differences between the European Union and the Umbrella Group (US, Japan, Canada, Australia) agreement was almost achieved in the Hague. A number of issues of concern to developing countries still need resolution.
• Flexibility mechanisms • LULUCF• Financing• Technology transfer • Capacity-building• Compliance• Adaptation
• capped or uncapped (EU and many developing countries want a cap in contrast to the US: affecting the size of market)
• secondary markets (EU and many developing countries want to eliminate secondary markets in the CDM - will decrease size of the market and incentives for private sector involvement)
• liability if a seller fails to deliver, i.e., seller vs buyer beware
• open market or regional allocations (ability of Africa and small countries to access the market)
• eligibility of LULUCF activities in CDM (next slide)
• adaptation fee - CDM or all three mechanisms (size of adaptation fund: ability to mainstream climate change into relevant sectors; ability to link near-and long-term issues)
Key Issues at COP-6
Flexibility Mechanisms (Art. 6, 12 and 17)
• Which, if any, LULUCF activities are eligible in the CDMafforestation, reforestation, slowing deforestation,
forest/rangeland/cropland management, agroforestryEU and some developing countries wanted to limit/eliminate
LULUCF activities in contrast to the US and other developing countries (LAC): will affect eligible activities under the PCF and access to CDM funds for clients
• How to address harvesting/regeneration and aggradation/ degradation (Art. 3.3 or 3.4)
• Whether to limit credits under Article 3.4 (EU and G77+China want to limit credits in contrast to the US, Canada, Japan)
• Whether the Business-as-usual uptake can be credited (US want discounted credits - EU and G77+China want no credit)
Key Issues at COP-6
LULUCF
• New window under the GEF for adaptation--key issue is who manages the window and establishes priorities-- the GEF Council/secretariat or the CDM Executive Board, accountable to the COP/MOP
• New Convention window under the GEF for technology transfer, capacity-building, national mitigation programs, etc. -- key issues are (i) the sources of funding, e.g., third GEF replenishment, voluntary contributions, ODA, fee on Article 17, and (ii) guidance by the COP
• Total annual resources for climate change funding, including the adaptation and Convention window, of $1 billion
Key Issues at COP-6
Financing
• Different views between developed and developing countries form an intergovernmental consultative group to
facilitate the sharing of information and assess approaches to address the barriers to technology transfer
• Funded under the Convention window of the GEF
Key Issues at COP-6
Technology Transfer
• Parties will establish a framework to guide the choice of activities that will assist Developing countries implement the Convention and participate in the Kyoto Protocol
• Funded under the Convention window of the GEF
Key Issues at COP-6
Capacity Building