June 01, 2015

Robustness in economic models with climate change

June 01, 2015/ Julia Turan

We are working on robust control in simple climate models coupled with economic growth, finance, and macro models. This effort is important for carbon pricing, understanding the impacts of robustly accounting for climate change, technical change, and other sources of uncertainty, not only on economic growth and macroeconomics, but also on asset prices as well as insurance pricing and green-house gas emission pricing.

Within the context of climate models are three contrasting approaches to robustness:

adapting to potential model misspecification
robustness adjustments for prior/posterior uncertainty
“smooth” models of ambiguity aversion

Decision theoretic frameworks exist for all of these applications, but their full consequences for economic models with climate change remains to be explored. To accomplish this we are developing numerical methods to support these analyses. In terms of discounting, our focal point is on the consequences of uncertainty. There is an extensive literature from asset pricing and macroeconomics that uses stochastic discounting as a device to adjust discount rates for cash flow riskiness. We are drawing on this literature and incorporating compensations for aversion to ambiguity and concerns about model misspecification into models that feature explicit uncertainty and climate impacts on the economy. We are also contrasting pricing implications from market economies with social valuation.

Coupled Economic-Climate Models with Carbon-Climate Response: The economics of global climate change is characterized by fundamental uncertainties including the appropriate reduced forms for climate dynamics, the specification of economic damages resulting from climate change, and mechanisms by which these damages will affect long-run economic growth. We have developed and implemented a novel theoretical and computational integrated assessment modeling approach that is a well-grounded means of summarizing the fundamental relationship between human activity and the global climate for purposes of economic analysis. Using a dynamic integrated assessment framework, this project makes several contributions to improving the analysis of these uncertainties:

First, we incorporate the cumulative climate response (CCR) function developed by Matthews et al. for representing the basic relationship between anthropogenic carbon emissions and increases in global mean temperature in a manner that is more directly policy relevant than the usual approach based on the equilibrium climate sensitivity.
Second, we adapt the tools developed by Hansen, Sargent and others for robustness analysis to address underlying model uncertainty in both economic and climate dynamics.
Third, we allow climate change to affect economic growth directly, in addition to its effect on output

We then develop and study a simple analytical model that yields insights and results on the key implications of these assumptions, as well as facilitating the interpretation of numerical results from a more general model. Among our findings is that the presence of robustness may result in either a decrease or increase in the optimal carbon tax and energy usage, depending among other factors on societal preferences.

Numerical Methods: In order to perform robustness analysis over a variety of fundamentally different models, we are developing PDE-based numerical method for solving robust stochastic equilibrium models in continuous time with optimal control. This approach allows us to uncover solutions for the entire state space and to perform a quick sweep over variety of models and parameters.

April 09, 2015

Illinois renewable portfolio standards

April 09, 2015/ Julia Turan

Recently enacted state Renewable Portfolio Standards (RPSs) collectively require that U.S. electricity generation by non-hydro renewables more than double by 2025. These goals are not certain to be met, however, because many RPSs apply cost caps that alter requirements if costs exceed targets. We have analyzed the 2008 Illinois RPS, which is fairly typical, and have found that at current electricity prices, complete implementation will require significant decreases in renewables costs, even given the continuation of federal renewables subsidies. While full implementation is possible, it is not assured.

We also find that the statutory design raises additional concerns about unintended potential consequences. First, the fact that wind power and solar carve-outs fall under a single cost cap leaves each technology vulnerable to the economics of the other. In failure mode, a less cost-effective technology can curtail deployment of a more cost-effective one. Second, adjacent-state provisions mean the bulk of the wind power requirement under the Illinois RPS can be met by existing facilities in Iowa, where new builds will likely also occur. We conclude that the Illinois RPS, and likely those of many other states, appear to combine objectives inherently in conflict and whose conflicts can create legislative failure: preferences for local jobs, for specific technolo- gies, for environmental benefits, and for low costs. Since RPSs are the principal policy mechanisms in the U.S. at present for combating climate change, it is important to revisiting existing legislation if necessary to ensure legislative success. The Illinois analysis can provide an example and guidelines for other states that will face similar pressure on their RPSs in the near future.

Click here to visit the RPS Calculator.

People:

Elisabeth Moyer | Alison Brizius | Sean Johnson | Lexi Goldberger | Joe Zhu

Recent Publications:

Johnson, Sean D., and Elisabeth J. Moyer. "Feasibility of US renewable portfolio standards under cost caps and case study for Illinois." Energy Policy 49 (2012): 499-514.

Elisabeth J. Moyer et al. "Feasibility and Implications of the Michigan 2012 Proposal 3 for a 25% State Renewable Portfolio Standard." RDCEP Policy Analysis Paper Series No. 12-02, October 2012.

April 02, 2015

Chicago Climate Online

April 02, 2015/ Julia Turan

Chicago Climate Online (C2O), a policy initiative of the University of Chicago Law School, is a climate change policy research tool that seeks to become a preeminent policy resource for researchers. It combines features of Wikipedia -- with summaries of current knowledge on climate policy topics -- and a database -- with a list of research articles on those topics. It is an open-access research tool that allows users to also upload, create, and organize their own content.

The focus of C2O is on policy issues, not climate science. Although climate science continues to develop rapidly, we take the core of existing climate science as given. C2O is not a place to debate the validity of this science. The interconnectedness of policy and science, however, makes clear demarcation between the two impossible. C2O was developed with a primary focus on climate change policy, with inclusion of more science-focused topics and references only as necessary.

Visit Website »

People

David Weisbach | Alison Brizius

April 01, 2015

RPS Calculator

April 01, 2015/ Julia Turan

The major policy instruments for mitigating climate change actually in use in the U.S. are subsidies provided to renewable energy. A popular means of subsidy is through state-level Renewable Portfolio Standards (RPSs), requirements enacted by many states that require a certain fraction of electricity must be derived from renewables. However, many state RPSs are infeasible because of “cost cap” provisions that do not permit renewables to be sufficiently competitive, and feasibility is generally not assessed before legislation is passed. The RPS calculator allows the user to explore the conditions for RPS success or failure in different states. The user can analyze and modify existing state statutes or design new statutes in states that do not have them. Users can explore the effects of parameters such as electricity prices, generation costs for wind and solar, interest rates, technology carveouts, and cost cap structure. Features under development include extension to all U.S. states (currently only IL and CA) and spatial variation in wind speed (wind capacity factor map).

RPS Calculator

People

Current: Elisabeth Moyer

Alumni: Sean Johnson | Lexi Goldberger | Joe Zhu

Recent Publications

Elisabeth J. Moyer et al. "Feasibility and Implications of the Michigan 2012 Proposal 3 for a 25% State Renewable Portfolio Standard." RDCEP Policy Analysis Paper Series No. 12-02, October 2012.

Johnson, Sean D., and Elisabeth J. Moyer. "Feasibility of US renewable portfolio standards under cost caps and case study for Illinois." Energy Policy 49 (2012): 499-514.

March 25, 2015

CIM-EARTH: a climate change policy modeling framework

March 25, 2015/ Julia Turan

The Community Integrated Model for Energy and Resource Trajectories for Humankind (CIM-EARTH) is an open-source modeling framework that allows for the easy specification of computable general equilibrium models, running the resulting simulations, and analyzing the results. This framework is meant to increase both the quality and transparency of integrated assessment modeling by providing open source modeling tools that incorporate the most modern computational methods.

Frameworks:

The AMPL-Source CIM-EARTH Framework (ASCEF) is a first version of the CIM-EARTH framework.
To facilitate adoption and the integration of advanced data processing and analysis services, we undertook an effort to move the implementation from AMPL to C++ and to adopt standard input and output formats. The result is what we call the Open-Source CIM-EARTH Framework (OSCEF).

Models:

CE-Trade: The trade model is used for studying the impacts on international trade of policies relevant to carbon mitigation. In particular, this model is used to assess carbon leakage and mechanisms such as border tax adjustments to reduce leakage.
CE-Energy: The energy model expands core capabilities of CIM-EARTH in order to represent the energy sector in ways more appropriate for policy analysis> The model disaggregated the representation of the U.S. electric power system to include renewable and non-renewable sources, peak and base-load power, and transmission.
CE-Bio: The bio model simulates the economics and lifecycle of biofuel production and use, including a detailed representation of the biofuels market, agriculture, and related services.
CE-Life: The distributional impacts model disaggregates the US consumers in the CE-Trade model by income and age, resulting in a model with 720 distinct consumers.

Structure of the production functions in the baseline CE model:

NOTE: Each node represents a production function. Nodes with vertical line inputs use Leontief functions; the other nodes are labeled with their elasticities of substitution. Table 2 shows the elasticities of substitution between domestic and import… — NOTE: Each node represents a production function. Nodes with vertical line inputs use Leontief functions; the other nodes are labeled with their elasticities of substitution. Table 2 shows the elasticities of substitution between domestic and imported commodities and the Armington international trade elasticities.

Studies:

People

Publications

Elliott, Joshua, and Don Fullerton. "Can a unilateral carbon tax reduce emissions elsewhere?." Resource and Energy Economics 36, no. 1 (2014): 6-21.

Choi, Sou-Cheng T., and Todd Munson. "OSCEF: the open-source CIM-EARTH framework user manual for version 1.0." Technical Report ANL/MCS-TM-339, Argonne National Laboratory, March 2014.

Joshua Elliott et al. "Unilateral carbon taxes, border adjustments, and carbon leakage." Theoretical Inquiries in Law 14 (2013): 207-243.

Elliott, Joshua, Ian Foster, Samuel Kortum, Gita Khun Jush, Todd Munson, and David Weisbach. "Unilateral Carbon Taxes Border Adjustments and Carbon Leakage" (2012). RDCEP Working Paper No. 12-04.

Joshua Elliott et al. "Impact on US Gasoline Prices of Eliminating Biofuels Production: An Equilibrium Analysis," February 2012. RDCEP Policy Analysis Paper No. 12-02.

Joshua Elliott et al. "Modeling of Land-Use Changes and Other Indirect Effects of Biofuel Production in CIM-EARTH." DOE Office of Biomass Program (2012).

Joshua Elliott et al. "Propagation of data error and parametric sensitivity in computable general equilibrium models." Computational Economics 39, no. 3 (2012): 219-241.

Elliott, Joshua, Ian Foster, Samuel Kortum, Gita Khun Jush, Todd Munson, and David Weisbach. "Unilateral Carbon Taxes Border Adjustments and Carbon Leakage" (2012). RDCEP Working Paper No. 12-04.

Joshua Elliott et al. "Impact on US Gasoline Prices of Eliminating Biofuels Production: An Equilibrium Analysis" (2012). RDCEP Working Paper No. 12-05, Argonne National Laboratory, 2011.

Elliott, Joshua, Margaret Loudermilk, Nirupama Rao, Ian Foster, Don Fullerton, & Todd Munson. "Building a Custom Initialization Data Product for a Life-cycle OLG Model." GTAP Working Paper. June 2011.

Joshua Elliott et al. "Modeling of Land-Use Changes & Other Indirect Effects of Biofuel Production in CIM-EARTH." Prepared for the U.S. Department of Energy Biomass Program, Final Report October 2011.

Elliott, Joshua, Ian Foster, Samuel Kortum, Todd Munson, Fernando Perez Cervantes, and David Weisbach. "Trade and carbon taxes." The American Economic Review (2010): 465-469.

Fullerton, Don, and Garth Heutel. "Analytical general equilibrium effects of energy policy on output and factor prices." The BE Journal of Economic Analysis & Policy 10, no. 2 (2010).

Joshua Elliott et al. "CIM-EARTH: Community Integrated Model of Economic and Resource Trajectories for Humankind." Mathematics and Computer Science Division Technical Memorandum ANL/MCS-TM-307.

February 18, 2015

Irrigation water

February 18, 2015/ Julia Turan

Summary of study:

Freshwater availability is relevant to almost all socioeconomic and environmental impacts of climate and demographic change and their implications for sustainability. We compare ensembles of water supply and demand projections driven by ensemble output from five global climate models. Our results suggest reasons for concern. Direct climate impacts to maize, soybean, wheat, and rice involve losses of 400-2,600 Pcal (8-43% of present-day total). Freshwater limitations in some heavily irrigated regions could necessitate reversion of 20-60 Mha of cropland from irrigated to rainfed management, and a further loss of 600-2,900 Pcal. Freshwater abundance in other regions could help ameliorate these losses, but substantial investment in infrastructure would be required. Models project that direct climate impacts to maize, soybean, wheat, and rice involve losses of 400-1,400 Pcal (8-24% of present-day total) when CO2 fertilization effects are accounted for or 1,400-2,600 Pcal (24-43%) otherwise.

People:

Neil Best | Joshua Elliott | Ian Foster | Michael Glotter

Alumni:

Flrke M, Wada Y, Eisner S, Fekete BM, Gosling SN, Haddeland I, Khabarov N, Ludwig F, Masaki Y, Olin S, Cynthia Rosenzweig, Satoh Y, Schmid E, Stacke T, Tang Q, Wisser D.

Recent Publications:

Deryng D, Elliott J, Ruane A, Folberth C, Muller C, Pugh T, Schmid E, Boote K, Gerten D, Jones J, Olin S, Schaphoff S, Yang H, Rosenzweig C. Disentangling uncertainties in future crop water productivity under climate change? Submitted to PNAS ISI-MIP special issue, January 2013.

Elliott J, Deryng D, Muller C, Frieler K, Konzmann M, Gerten D, Glotter M, Flrke M, Wada Y, Best N, Eisner S, Fekete BM, Folberth C, Foster I, Gosling SN, Haddeland I, Khabarov N, Ludwig F, Masaki Y, Olin S, Rosenzweig C, Ruane AC, Satoh Y, Schmid E, Stacke T, Tang Q, Wisser D. Constraints and potentials of future irrigation water availability on agricultural production under climate change. Proceedings of the National Academy of Sciences, 2014 ;111(9):3239–3244.

December 01, 2014

Evaluating the utility of dynamical downscaling in agricultural impacts projections

December 01, 2014/ Julia Turan

Dssat probability distributions of 1980-1998 rain-fed maize yield driven by all climate products. a and b show yields driven by ccsm and cgcm output, respectively. observation-driven yield distributions are duplicated in both panels (black line) and… — Dssat probability distributions of 1980-1998 rain-fed maize yield driven by all climate products. a and b show yields driven by ccsm and cgcm output, respectively. observation-driven yield distributions are duplicated in both panels (black line) and mapped on right (time-averages, with outline demarking the corn belt, counties with ≥ 1/4 land cultivated with maize). Aggregation is by county and not normalized for size or total yield. Arrows and star in a and b show average county yiled. yields driven by non-bias-corrected inputs (dashed) are generally skewed low, with the skew worse for dynamical downscaling than for simply interpolated gcm inputs. Bias-correcting climate inputs (solid) largely eliminates distributional discrepancies against the observation set.

Interest in estimating the potential socioeconomic costs of climate change has led to increasing use of dynamical downscaling: nested modeling in which regional climate models (RCMs) are driven with general circulation model (GCM) output to produce fine-spatial-scale climate projections for impacts assessments. We evaluate here whether this computationally intensive approach significantly alters projections of food supply. Our results suggest that it does not. We simulate U.S. maize yields with the widely-used DSSAT crop model, driven by two GCMs, each in turn downscaled by two RCMs. While RCMs correct some GCM biases related to fine-scale geographic features, errors in yield are dominated by broad-scale (100s of kms) GCM systematic errors that RCMs cannot compensate for. Once a simple statistical bias correction is applied, GCM- and RCM-driven U.S. maize yields are essentially indistinguishable. These results support previous suggestions that the benefits for impacts assessments of dynamically downscaling raw GCM output may not be sufficient to justify its computational demands.