Policy and Science have Policy and Science have Complementary Roles in Mitigating Complementary Roles in Mitigating
Climate ChangeClimate Change
Case #1: Stratospheric Ozone Case #1: Stratospheric Ozone Depletion and the Montreal ProtocolDepletion and the Montreal Protocol
The Antarctic Ozone Hole continues to grow in size – in 2000 it was larger than North America!
Simultaneously, the ozone depletion increases in severity, reaching nearly 100% at certain altitudes in 2000.
Not only is the Ozone Hole getting larger, but it persists for longer times
Effects of the Montreal Protocol on Effects of the Montreal Protocol on Atmospheric Cl and Br LoadingAtmospheric Cl and Br Loading
1985 – Vienna Convention Organizes the international effort to ban CFC’s
1987 – Montreal Protocol Reduce CFC production to 50% of 1986 levels by 1998
1990 – London Ban on all CFC production by 2000 Accelerated phase-out of replacement gases
1992 – Copenhagen, 1997 Montreal, 1999 – Beijing Halons, CCl4, CH3Br to be eliminated by 2005
Future OFuture O33 Levels Levels
• The threshold level for Antarctic ozone hole formation is ~ 2 ppb Cl• The first Antarctic ozone holes were observed in the mid 1980’s• Atmospheric Cl loading peaked in ~1996 at 3.3 ppb and appears to be decreasing• Current models indicate recovery by ~ 2050 ± 10
Lessons Learned Lessons Learned from the Montreal from the Montreal Protocol ProcessProtocol Process
• Subsequent acceleration of the ODP phaseouts were made based on the continued improvement of remote sensing data and model forecasts•These accelerations in schedule were crucial for avoiding even larger long-term impacts• Action prior to 1987 (13 year delay from initial warnings) may have averted occurrence of the Antarctic ozone hole
The Montreal Protocol process serves as the paradigm for effective interaction between science and policy in dealing with global climate change issues.
Case #2: Greenhouse Gas Emissions Case #2: Greenhouse Gas Emissions and the Kyoto Protocol Processand the Kyoto Protocol Process
The Link Between The Link Between COCO22 and Global and Global WarmingWarming
There is a clear correlation between the geologic CO2 record (TOP) and the geologic surface temperature record (BOTTOM) over the last 1000 years.
State-of-the-art global climate models forecast that future increases in atmospheric CO2 levels will be linked to corresponding increases in the mean global surface temperature.
The question of HOW MUCH will temperatures increase is based on model assumptions and estimated CO2 levels.
CO2
Temp
Recent Surface Recent Surface Temperature Temperature VariationsVariations
Surface temperatures have shown significant fluctuation over the last 1000 years.
However, the trend since 1800 has been steadily increasing.
Temperatures rose ~ 0.6° C over the last century with land areas heating more than the oceans.
Note that the increases in the 1900’s occurred abruptly. The cause of these changes is still debated although it can be captured reproducibly in the most sophisticated models.
The Effects of The Effects of Increasing Surface Increasing Surface TemperaturesTemperatures
Surface temperatures may increases may be expressed in terms of the mean (average) temperature or temperature variance
A uniform increase in mean temperature would cause all areas to become hotter.
Increases in the variance of surface temperatures would lead to more extreme weather conditions and more unstable events (storms, ENSO, monsoons, etc)
Increasing mean and variance would lead to warmer and more volatile global weather patterns.
Climate Change Climate Change ScenariosScenarios
The IPCC 2001 report uses several different scenarios as the basis for its forecasts
The scenarios balance different drivers: Economic vs EnvironmentalGlobal vs Regional
Different Scenarios Have Very Different Different Scenarios Have Very Different ImpactsImpacts
The Impacts of Atmospheric COThe Impacts of Atmospheric CO22 Loading Loading Extend Far into the FutureExtend Far into the Future
The timescales for recovery from atmospheric CO2 loading are 100 – 1000+ years due to the slow reaction times and large thermal inertia of the oceans and ice caps
Modeling Surface Modeling Surface Temperature Temperature
Change: Change: Regional vs. Regional vs.
GlobalGlobal
Models forecast significantly larger effects at high latitudes than near the equator and larger effects in the Northern Hemisphere than in the Southern Hemisphere.
Global Climate Models Capture Surface Global Climate Models Capture Surface Temperature VariationsTemperature Variations
Modeling Global Modeling Global Temperature Temperature
ChangeChange
Models do well capturing the past behavior of the climate, but diverge on their forecasts of future temperatures.
The uncertainties in these forecasts presents the most probable range of temperatures that one might associate with different scenarios.
Compare the forecasted changes in temperature for 2100 with the 0.6° C rise in global mean surface temperature from 1900-2000.
Indicators of Surface Temperature Indicators of Surface Temperature ChangeChange
Emissions Scenarios Are Difficult to Emissions Scenarios Are Difficult to PredictPredict
… … and Have Very Different Impactsand Have Very Different Impacts
Uncertainty in Uncertainty in Global WarmingGlobal Warming
Uncertainties exist in the forecasts for potential global warming even for stabilized concentrations of greenhouse gases.
Economic Impact of Different Economic Impact of Different COCO22 Stabilization Scenarios Stabilization Scenarios
The ultimate estimated economic impact of CO2 emissions regulation depends on the target stabilization level chosen.
UNFCCCUNFCCC - - ARTICLE 1: ARTICLE 1: DEFINITIONSDEFINITIONS
1...."Adverse effects of climate change" means changes in the physical environment or biota resulting from climate change which have significant deleterious effects on the composition, resilience or productivity of natural and managed ecosystems or on the operation of socio-economic systems or on human health and welfare.
2...."Climate change" means a change of climate which is attributed directly or indirectly to human activity that alters the composition of the global atmosphere and which is in addition to natural climate variability observed over comparable time periods.
3...."Climate system" means the totality of the atmosphere, hydrosphere, biosphere and geosphere and their interactions.
4...."Emissions" means the release of greenhouse gases and/or their precursors into the atmosphere over a specified area and period of time.
UNFCCCUNFCCC - - ARTICLE 1: ARTICLE 1: DEFINITIONSDEFINITIONS
5...."Greenhouse gases" means those gaseous constituents of the atmosphere, both natural and anthropogenic, that absorb and re-emit infrared radiation.
6...."Regional economic integration organization" means an organization constituted by sovereign States of a given region which has competence in respect of matters governed by this Convention or its protocols and has been duly authorized, in accordance with its internal procedures, to sign, ratify, accept, approve or accede to the instruments concerned.
7...."Reservoir" means a component or components of the climate system where a greenhouse gas or a precursor of a greenhouse gas is stored.
8...."Sink" means any process, activity or mechanism which removes a greenhouse gas, an aerosol or a precursor of a greenhouse gas from the atmosphere.
9...."Source" means any process or activity which releases a greenhouse gas, an aerosol or a precursor of a greenhouse gas into the atmosphere.
UNFCCCUNFCCC
ARTICLE 2: OBJECTIVE
The ultimate objective of this Convention and any related legal instruments that the Conference of the Parties may adopt is to achieve, in accordance with the relevant provisions of the Convention, stabilization of greenhouse gas concentrations in the atmosphere at a level that would prevent dangerous anthropogenic interference with the climate system. Such a level should be achieved within a time-frame sufficient to allow ecosystems to adapt naturally to climate change, to ensure that food production is not threatened and to enable economic development to proceed in a sustainable manner.
The Greenhouse EffectThe Greenhouse Effect
COCO22 Emissions from Fossil Fuel Emissions from Fossil Fuel BurningBurning
COCO22 Emissions from Land Use Emissions from Land Use ChangeChange
Historical and Projected Global Historical and Projected Global Population & Energy ConsumptionPopulation & Energy Consumption
Changes in Global Energy Changes in Global Energy Consumption by RegionConsumption by Region
Energy consumption in Asia and Latin America is projected to more than double in the next 20 years!
Energy consumption in Africa and the Middle East should not lag far behind
Even technologically advanced nations are expected to increase energy consumption by up to 40% in the next 2 decades
Global COGlobal CO22 Emissions Emissions
Projections suggest rapid rise in CO2 emissions from Developing Nations, surpassing the emissions from Developed Nations by 2020.
CO2 emissions from oil are projected to dominate the anthropogenic contributions over the next 20 years
Global Energy Global Energy Consumption by Consumption by RegionRegion
Industrialized Nations: Energy consumption will continue to rise over the next 20 years
Developing Nations: Nearly exponential growth in energy consumption over next 20 years
Developing and Industrialized nations projected to have similar energy consumption by ~ 2020
EE = Eastern Europe FSU = Former Soviet Union
US Oil ConsumptionUS Oil Consumption
Hubbert’s PeakHubbert’s Peak
It is thought that global oil production will peak around 2005 and then begin to decline. This forecast is made based on known reserves and the rate of new discoveries. King Hubbert made the first prediction of this type in the 1950’s when he correctly predicted that oil production in the continental US would peak in 1968. The maximum oil production year is thus known as “Hubbert’s Peak”.
Energy Economics 2Energy Economics 2