Climate Change: The Move to Action (AOSS 480 // NRE 480)

Climate Change: The Move to Action(AOSS 480 // NRE 480) Richard B. Rood Cell: 301-526-8572 2525 Space Research Building (North Campus) rbrood@umich.edu http://aoss.engin.umich.edu/people/rbrood Winter 2012 March 13, 2012

Class News • Ctools site: AOSS_SNRE_480_001_W12 • 2008 and 2010 Class On Line: • http://climateknowledge.org/classes/index.php/Climate_Change:_The_Move_to_Action • Projects: • First Meetings: • Education: 23 February • Cities: 8 March • Regional: 13 March • Universities: 13 March

The Current Climate (Released Monthly) • Climate Monitoring at National Climatic Data Center. • http://www.ncdc.noaa.gov/oa/ncdc.html • State of the Climate: Global

Reading Response: Due March 15, 2012 • Pacala and Socolow, “Stabilization Wedges,” Science, 2004 (link) • Socolow, “Wedges Reaffirmed,” Climate Central, 2011 (link) • Reading responses of roughly one page (single-spaced). The responses do not need to be elaborate, but they should also not summarize the reading. They should be used by you as think pieces to refine your questions and insight from the readings. They must be submitted via CTools at least two hours before the start of lecture for the relevant readings.

Wedges on the Web • Carbon Mitigation Initiative @ Princeton University

Today • Structure of problem solving • Policy Interface 1 • Uncertainty Fallacy • Policy Interface 2 • Global Mitigation • Elements of the Political Argument

Granularity • No matter how we cut through this problem we come to the conclusion that there is a lot of granularity within the problem. This granularity represents complexity, which must be used to develop a portfolio of solutions rather than to classify the problem as intractable.

The previous viewgraphs have introduced “granularity” • This is a classic short-term versus long-term problem. • Ethics • Economics • Reaction versus anticipation • Similarly, regional versus global • Rich and poor • Competing approaches • Mitigation versus adaptation • Transportation versus Electrical Generation • This versus that

LOCAL GLOBAL SPATIAL We arrive at levels of granularity Need to introduce spatial scales as well WEALTH Sandvik: Wealth and Climate Change TEMPORAL NEAR-TERM LONG-TERM Small scales inform large scales. Large scales inform small scales.

LONG SHORT There are short-term issues important to climate change. What is short-term and long-term? Pose that time scales for addressing climate change as a society are best defined by human dimensions. Length of infrastructure investment, accumulation of wealth over a lifetime, ... ENERGY SECURITY Election time scales CLIMATE CHANGE ECONOMY 25 years 0 years 50 years 75 years 100 years

Structure of Problem Solving(http://glisaclimate.org/home )

Complexity challenges disciplinary intuition • The details of the problem often de-correlate pieces of the problem. • What do I mean? Think about heat waves? • This challenges the intuition of disciplined-based experts, and the ability to generalize. • For example --- Detroit is like Chicago. • The consideration of the system as a whole causes tensions – trade offs - optimization Problem Solving Unification Integration Knowledge Generation Reduction Disciplinary

Policy • A natural reaction to greenhouse gas emissions is to look to government, to the development of policy to address the problems that we are faced with.

Policy • What do we look to policy to accomplish? • Some common, relevant purposes of policy • Stimulate technology: Provide incentives or disincentives for behavior. (Often through financial or market forces.) • Set regulations: Put bounds on some type of behavior, with penalties if the bounds are exceeded. • Make internal some sort of procedure or behavior or cost that is currently external. • A more abstract point of view • Represents collective values of society: what is acceptable and what is not. • Interface with the law? • Provides the constraints and limits, the checks and balances in which we run our economy.

Policy-climate science interface (1) • It is sensible to look at governance and policy to address climate change • It’s a “greater good” problem • It relates to natural resources and waste from the use of natural resources • It impacts economic and national security • There is precedence (Ocean and Acid Rain) • Given the relation to energy and wealth it is natural to expect there will not to be a “one size fits all solution” for climate change. • One size fits all is one of the most common traps that “managers” and “leaders” fall into. • Feeds polarization and rhetoric • Guided to one size by political interests

Knowledge from Predictions Motivates policy Uncertainty of the Knowledge that is Predicted Policy Science: Knowledge and Uncertainty • Uncertainty always exists • New uncertainties will be revealed • Uncertainty can always be used to keep policy from converging

Science: Knowledge and Uncertainty Knowledge from Predictions Motivates policy Uncertainty of the Knowledge that is Predicted Policy • Uncertainty always exists • New uncertainties will be revealed • Uncertainty can always be used to keep policy from converging What we are doing now is, largely, viewed as successful. We are reluctant to give up that which is successful. We are afraid that we will suffer loss.

A Premise • Climate change problem cannot be solved in isolation. • Requires integration with all elements of society. • Requires identification of reasons to motivate us to take action • Apparent benefit • Excess Risk

A Conclusion about Policy • Policy cannot stand alone as our response to climate change. • Every person and every group of people will be impacted by climate change, and therefore, by policy to address climate change. • In fact, some feel that they are more impacted by policy than by climate change. • Policy has to not only be effective, but it has to include and balance the interests of all who have a stake. • Policy opportunity • Policy represents our values – our societal belief system. • It sets the bounds on behavior to benefit society

The Uncertainty Fallacy • That the systematic reduction of scientific uncertainty will lead to development of policy is a fallacy. • Uncertainty can always be used to keep policy from converging. • That is – this is a political issue • What might lead to successful policy efforts?

The Official Policy is: • United Nations Framework Convention on Climate Change • Framework Convention on Climate Change

What is COP? • COP is the Conference of Parties • Parties are those countries who have signed the United Nations Framework Convention on Climate Change. There are 192 signatories. • Essential Background UNFCCC

Michigan Observer Status • Framework Convention Parties and Observers • Parties are signatories of Framework Convention • Observers are invited to the meeting for participation, transparency, and accountability • United Nations Representatives • Intergovernmental Organizations • Non-governmental Organizations • Virtual Participation

Framework Convention on Climate Change(US in part of this.) • UN Framework Convention on Climate Change (1992, non-binding, voluntary, 192 signers) • Reduce CO2 Emissions in 2000 to 1990 levels • Inventories of greenhouse gas emissions • Mitigate Climate Change • Mid-1990’s • No reduction in emissions • Evidence of warming and impacts

Framework Convention on ClimateChange

Development of International Approach to Climate Change 2009 1988 1992 1995 1997 2001 2007 IPCC established Framework Convention(UNFCCC) Kyoto Protocol CopenhagenAccord Scientific assessment Non-binding aim Binding emissions target Keep warming less than 2 C

Dangerous climate change? • What is dangerous?

Stern Report: Influential: Useful for thinking about problem • Draws on recent science which points to ‘significant risks of temperature increases above 5°C under business-as-usual by the early part of the next century’ — other studies typically have focused on increases of 2–3°C. • Treats aversion to risk explicitly. • Adopts low pure time discount rates to give future generations equal weight. • Takes account of the disproportionate impacts on poor regions.

Dangerous climate change? Stern, 2006

Stern Report • Considered a radical revision of climate change economics. • If we don’t act now it will cost between 5% and 20% of gross domestic product (an aggregate measure of economy.) • Stands in contrast to many studies that usually come to numbers of closer to 1% • The idea that initiation of a policy with a slow growth rate will have little impact on the economy or environment in the beginning, but will ultimately become important when the nature of expenditures is more clear.

Some carry away messages • Determine what is a tolerable ceiling for carbon dioxide. • Gives cap for a cap and trade system. • Tolerable ceilings have been posed as between 450 and 550 ppm. • Ice sheet melting and sea level? • Oceanic circulation / The Gulf Stream? • Ocean acidification? • Determine a tolerable measure of increased temperature • Copenhagen Accord (2009)  2o C

Dangerous climate change? Stern, 2006

All Parties agree to: 4.1.b. Mitigate emissions and enhance sinks 4.1.c. Promote technology development and transfer 4.1.e. Cooperate on research and observation Developed Countries’ aim to return emissions to 1990 levels by the end of the century 1992 Convention Commitments

Assessment • Mid-1990’s • No reduction in emissions • Evidence of warming and impacts • 2001 • No reduction in emissions • Evidence of warming and impacts • 2007 • No reduction in emissions • Evidence of warming and impacts

Increase of Atmospheric Carbon Dioxide (CO2) “This generation has altered the composition of the atmosphere on a global scale through…a steady increase in carbon dioxide from the burning of fossil fuels.” --Lyndon Johnson Special Message to Congress, 1965 Data and more information

Kyoto Protocol followed 1995 assessments • Is the Kyoto Protocol still relevant?

Kyoto Protocol • Kyoto Protocol (December, 1997, binding limits on or reduction of emissions) • Must be signed (155 signers (?186)) and ratified • At least 55 countries • That represent 55 % or more of emissions • Open for signatures on March 16, 1998 • Went into effect on February 16, 2005 • After Russia signed and ratified

Kyoto Protocol Requirements • Developed nations reduce their emissions 5.2% below 1990 emissions • Reduction (increases) vary across countries • Relaxed a little over the years to attract signers • (Treaty: U.S. 7% reduction: Actual: 12% higher in 2004, 30% by 2012) • Addresses “six” greenhouse gases (CO2, Methane CH4, Nitrous Oxide N2O, hydrofluorocarbons, perfluorocarbons, sulphur hexafluoride) • Commitment period 2008-2012 • Set of other activities • Improve “local emission factors” • Inventories of emissions and sinks • Mitigation and adaptation plans • Environmentally sound technology diffusion to developing nations

Kyoto Protocol Issues • Amount and distribution for limits and reductions • What greenhouse gases to include • Developing countries in or out of emission requirements • Trading, market-based mechanisms • Role of removing greenhouse gases

Kyoto Protocol: Important Add ons • Market-based mechanisms • Emissions trading • Joint implementation • Clean development mechanisms

Flexibility in Achieving Targets • “What” flexibility • Targets apply to CO2-equivalent emissions of basket of six GHGs • Can use carbon sinks (e.g. forests) as offsets • “When” flexibility • Five-year commitment period • Banking • “Where” flexibility • Market mechanisms: ET, JI, CDM Thanks to Rosina Bierbaum

“Flaws” in Kyoto Protocol • Participation of Developing Countries • Large populations, large projected growth • Participation of the United States • 25 % of greenhouse gas emissions • Other “flaws” • Does not go far enough: Emission goals don’t adequately mitigate dangerous climate change • 2008-2012 commitment period – then what?

Beyond 2012 • Conference of Parties, Copenhagen 2009 • Copenhagen Accord

PA1: Just a Theory • A common statement is that greenhouse gas is just a theory, equating theory with conjecture. • Theory is not conjecture, it is testable. • Theory suggests some amount of cause and effect – a physical system, governed by quantitative conservation equations. • Theory is not fact, it can and will change. • Need to consider the uncertainty, and the plausibility that the theory might be wrong. • Often it is stated in this discussion that gravity is only a theory. • True, and the theory of gravity is a very useful theory, one put forth by Newton. • True, we don’t exactly understand the true nature of the force of gravity, there are “why” questions. • Formally, Newton’s theory of gravity is incorrect – that’s what Einstein did. • Still, it is a very useful and very accurate theory, that allows us, for example, to always fall down and never fall up – and go to the Moon with some confidence.

PA2: Greenhouse Effect • This is generally not a strongly argued point. Warming of the surface due to greenhouse gases make the planet habitable. • Habitable? Water exists in all three phases? • Water and carbon dioxide and methane are most important natural greenhouse gases. • Often a point of argument that water is the “dominant” gas, so traces of CO2 cannot be important. • Water is dominant … often said 2/3 rds of warming. Because there is so much water in the ocean, the amount of water vapor in the atmosphere is largely determined by temperature. (The relative humidity.) • This is where it is important to remember the idea of balance, the climate is in balance, and it is differences from this balance which we have co-evolved with that are important. • Burning fossil fuels is taking us away from this balance. It is like opening or closing a crack in the window … it makes a big difference.

PA3: What happens to this CO2 • A “new” political argument: CO2 from fossil fuels is small compared to what comes from trees and ocean. True. But a lot goes into trees and oceans as well. So it is the excess CO2, the CO2 on the margin that comes from fossil fuel burning. Not all of this goes into the trees and oceans, and it accumulates in the atmosphere. • There are 8.6 Petagrams C per year emitted • 3.5 Pg C stay in atmosphere • 2.3 Pg C go into the ocean • 3.0 Pg C go into the terrestrial ecosystems • Terrestrial ecosystems sink needs far better quantification • Lal, Carbon Sequestration, PhilTransRoySoc 2008 • It’s a counting problem! One of our easier ones.

PA4: Cycles • Some say that there are cycles, they are natural, they are inevitable, they show that human have no influence. • Cycles? yes  natural? Yes • Inevitable  There are forces beyond our control • We can determine what causes cycle; they are not supernatural • Greenhouse gases change • “Life” is involved  ocean and land biology • Humans are life  This is the time humans release CO2

Climate Change: The Move to Action (AOSS 480 // NRE 480)