Marilyn A. Brown
- School of Public Policy
- Center for Urban Innovation
- Climate and Energy Policy Laboratory
- Technology Policy and Assessment Center
Marilyn Brown is a Regents' and Brook Byers Professor of Sustainable Systems in the School of Public Policy. She joined Georgia Tech in 2006 after a distinguished career at the U.S. Department of Energy's Oak Ridge National Laboratory, where she led several national climate change mitigation studies and became a leader in the analysis and interpretation of energy futures in the United States.
Her research focuses on the design and impact of policies aimed at accelerating the development and deployment of sustainable energy technologies, with an emphasis on the electric utility industry, the integration of energy efficiency, demand response, and solar resources, and ways of improving resiliency to disruptions. Her books include Fact and Fiction in Global Energy Policy (Johns Hopkins University Press, 2016), Green Savings: How Policies and Markets Drive Energy Efficiency (Praeger, 2015), and Climate Change and Global Energy Security (MIT Press, 2011). She has authored more than 250 publications. Her work has had significant visibility in the policy arena as evidenced by her numerous briefings and testimonies before state legislative bodies and Committees of both the U.S. House of Representatives and Senate.
Dr. Brown co-founded the Southeast Energy Efficiency Alliance and chaired its Board of Directors for several years. She has served on the Boards of the American Council for an Energy-Efficient Economy and the Alliance to Save Energy, and was a commissioner with the Bipartisan Policy Center. She has served on eight National Academies committees and is an Editor of Energy Policy and an Editorial Board member of Energy Efficiency and Energy Research and Social Science. She served two terms (2010-2017) as a Presidential appointee and regulator on the Board of Directors of the Tennessee Valley Authority, the nation’s largest public power provider. From 2014-2018 she served on DOE’s Electricity Advisory Committee, where she led the Smart Grid Subcommittee.
- Ph.D., Ohio State University, Geography
- M.R.P., University of Massachusetts, Regional Planning
- B.A., Rutgers University, Political Science
- 2017, Regents' Professor
- Brook Byers Chaired Professor, Institute of Sustainable Systems, 2014-2018.
- 2016 Alliance to Save Energy "Star of Energy Efficiency"
- DOE Electricity Advisory Board, 2014-2018
- 2013, “Who’s Who in Sustainability”, Atlanta Business Chronicle.
- DOE Ambassador for Clean Energy Education and Empowerment, 2013-2017
- 2012 Southface Energy Institute Award of Excellence
- Presidential Appointment: Board of Directors, TVA, 2010-2017.
- 2007 Co-recipient of the Nobel Prize for co-authorship of the IPCC Report on Mitigation of Climate Change
- Clean Energy
- Climate Change Adaptation
- Climate Change Mitigation
- Energy Efficiency
- Energy Markets
- Energy, Climate and Environmental Policy
- Financing and Subsidies
- Information Programs
- Innovation and Diffusion
- Institutional Analysis
- Market-based Incentives
- Regulations and Standards
- Smart Grid
- Voluntary Programs
- United States
- United States - Georgia
- United States - Southeast
- PUBP-3350: Energy Policy
- PUBP-6201: Public Policy Analysis
- PUBP-6701: Energy Technol & Policy
- PUBP-8833: Special Topics
- The Economic and Environmental Performance of Biomass Power as an Intermediate Resource for Power Production
In: Utilities Policy [Peer Reviewed]
Electricity powered by biomass is expanding. We examine four recent biopower plants and global benchmarks to assess their overall performance, confirming the characterization of biomass as an “intermediate” resource for power production. Electricity from biomass is more expensive than energy efficiency, natural gas, wind, or solar but substantially less expensive than new coal or nuclear plants. Compared to coal and natural gas per MWh produced, the NOx and SO2 emissions of biopower are also intermediate. We document that current investments in biopower can be attributed to an array of stakeholder value propositions extending beyond basic economic and environmental metrics.
- Understanding renewable energy policy adoption and evolution in Europe: The impact of coercion, normative emulation, competition, and learning
In: Energy Research and Social Sciences [Peer Reviewed]
- Climate research priorities for policy-makers, practitioners, and scientists in Georgia, USA
In: Environmental Management
Climate change has far-reaching effects on human and ecological systems, requiring collaboration across sectors and disciplines to determine effective responses. To inform regional responses to climate change, decision-makers need credible and relevant information representing a wide swath of knowledge and perspectives. The southeastern U. S. State of Georgia is a valuable focal area for study because it contains multiple ecological zones that vary greatly in land use and economic activities, and it is vulnerable to diverse climate change impacts. We identified 40 important research questions that, if answered, could lay the groundwork for effective, science-based climate action in Georgia. Top research priorities were identified through a broad solicitation of candidate research questions (180 were received). A group of experts across sectors and disciplines gathered for a workshop to categorize, prioritize, and filter the candidate questions, identify missing topics, and rewrite questions. Participants then collectively chose the 40 most important questions. This cross-sectoral effort ensured the inclusion of a diversity of topics and questions (e.g., coastal hazards, agricultural production, ecosystem functioning, urban infrastructure, and human health) likely to be important to Georgia policy-makers, practitioners, and scientists. Several cross-cutting themes emerged, including the need for long-term data collection and consideration of at-risk Georgia citizens and communities. Workshop participants defined effective responses as those that take economic cost, environmental impacts, and social justice into consideration. Our research highlights the importance of collaborators across disciplines and sectors, and discussing challenges and opportunities that will require transdisciplinary solutions.
- Low-carbon technology diffusion in the decarbonization of the power sector: Policy implications
In: Energy Policy
The Chinese power sector faces a significant challenge in attempting to mitigate its CO2 emissions while meeting its fast-growing demand for electricity. To address this challenge, an analytical framework is proposed that incorporates technological learning curves in a technology optimization model. The framework is employed to evaluate the technology trajectories, resource utilization and economic impacts in the power sector of Tianjin in 2005–2050. Using multi-scenario analysis, this study reveals that CO2 emissions could be significantly reduced if relevant mitigation policies are introduced. The main technologies adopted are ultra-super-critical combustion, integrated gasification combined cycle, wind power, hydropower, biomass power, solar photovoltaic power and solar thermal power. Despite uncertainties, nuclear power and CO2 capture and storage technology could be cost competitive in the future. The CO2 emissions cap policy has the advantage of realizing an explicit goal in the target year, while the renewable energy policy contributes to more cumulative CO2 emissions reduction and coal savings. A carbon taxof 320 CNY/ton CO2 would contribute to early renewable energy development and more CO2 reduction in the short run. A sensitivity analysis is conducted to examine the impacts on the power system of learning rates, technology cost reductions and energy fuel price trajectories.
- Smart grid governance: An international review of evolving policy issues and innovations
In: WIREs Energy and Environment [Peer Reviewed]
The electric power systems of many industrialized nations are challenged by the need to accommodate distributed renewable generation, increasing demands of a digital society, growing threats to infrastructure security, and concerns over global climate disruption. The “smart grid”—with a two‐way flow of electricity and information between utilities and consumers—can help address these challenges, but various financial, regulatory, and technical obstacles hinder its rapid deployment. An overview of experiences with smart grids policies in pioneering countries shows that many governments have designed interventions to overcome these barriers and to facilitate grid modernization. Smart grid policies include a new generation of regulations and finance models such as regulatory targets, requirements for data security and privacy, renewable energy credits, and various interconnection tariffs and utility subsidies.
- Estimating residential energy consumption in metropolitan areas: A microsimulation approach
In: Energy [Peer Reviewed]
- Recent Developments and Future Directions at Energy Policy
In: Energy Policy [Peer Reviewed]
- Infrastructure Ecology: An Evolving Paradigm for Sustainable Urban Development
In: Journal of Cleaner Production [Peer Reviewed]
Increasing urbanization places cities at the forefront of achieving global sustainability. For cities to become more sustainable, however, the infrastructure on which they rely must also become more productive, efficient and resilient. Unfortunately the current paradigm of urban infrastructure development is fragmented in approach lacking a systems perspective. Urban infrastructure systems are analogous to ecological systems because they are interconnected, complex and adaptive components that exchange material, information and energy among themselves and to and from the environment, and exhibit characteristic scaling properties that can be expressed by Zipf's Law. Analyzing them together as a whole, as one would do for an ecological system, provides a better understanding about their dynamics and interactions, and enables system-level optimization. The adoption of this “infrastructure ecology” approach will result in urban (re)development that requires lower investment of financial and natural resources to build and maintain, is more sustainable (e.g. uses less materials and energy and generates less waste) and resilient, and enables a greater and more equitable opportunities for the creation of wealth and comfort. The 12 guiding principles of infrastructure ecology will provide a set of goals for urban planners, engineers and other decision-makers in an urban system for urban (re)development.
- Machine Learning Approaches to Estimating Commercial Building Energy Consumption
In: Applied Energy [Peer Reviewed]
- Peak Shifting and Cross-Class Subsidization: The Impacts of Solar PV on Changes in Electricity Costs
In: Energy Policy [Peer Reviewed]
- Carbon Pricing and Energy Efficiency: Pathways to Deep Decarbonization of the U.S. Electric Sector
Despite the commitment of the Paris agreement to pursue efforts to limit end-of-century global warming to 1.5°C above pre-industrial levels, few have studied mitigation pathways consistent with such a demanding goal. This paper uses a fully integrated engineering-economic model of the U.S. energy system, to explore the ability of the U.S. electricity sector to operate within a budget of 44 gigatons of CO2 (GtCO2) between 2016 and 2040 - almost 20 percent less than projected. Our modeling results suggest that carbon taxes coupled with strong energy-efficiency policies would produce synergistic effects that could meet deep decarbonization goals. Combining energy-efficiency initiatives with a $10/tCO2 tax rising to $27/tCO2 in 2040 (in $2013) would achieve the U.S. electric sector's carbon budget with a net savings to the U.S. economy. A $20/tCO2 tax rising to $53/tCO2 in 2040 would also stay below this budget, but it would cost more if not coupled with strong energy efficiency. U.S. regions will win or lose depending on their generation mix and how carbon tax revenues are recycled.
- The Economics of Four Virginia Biomass Plants
Global electricity generated from biomass more than tripled between 2000 and 2016, and it is forecast to grow at an increasing pace through 2050. Electricity generation from biomass is also expanding in the United States, particularly in the Southeast. Given the continued growth and policy support for biomass electricity generation, this paper assesses the economics of four Virginia biomass plants, three converted from coal plants in 2012 and one purchased and expanded in 2004. The goal is to estimate the levelized cost of electricity (LCOE) generated from the plants as a metric of their level of competitiveness with respect to alternative ways of meeting electricity demand in the region. The LCOE of the four plants range from $93 to $143/MWh, about 40-53% more expensive than new solar and wind today and is double the cost of energy efficiency. Even with the inclusion of federal subsidies and environmental credits, Dominion’s biomass conversions are not competitive. Overall, our analysis underscores the risks associated with investing in large, long-lived generation assets at a time when technologies and markets are rapidly evolving.
- The Economics of Four Virginia Biomass Plants
Global electricity generated from biomass more than tripled between 2000 and 2016, and it is forecast to grow at an increasing pace through the year 2040. Electricity generation from biomass is also expanding in the United States, particularly in the Southeast. Given the continued growth and policy support for biomass electricity generation, this paper assesses the economics of four Virginia biomass plants, three converted from coal plants in 2012 and one purchased and expanded in 2004. The goal is to estimate the levelized cost of electricity (LCOE) generated from the plants as a metric of their level of competitiveness with respect to alternative ways of meeting electricity demand in the region. The LCOE of the four plants range from $93 to $143/MWh, about 40-53% more expensive than new solar and wind today. Even with the inclusion of federal subsidies and environmental credits, Dominion’s biomass conversions are not competitive with several other established sources of electricity and affordable energy-efficiency options. Overall, our analysis underscores the risks associated with investing in large, long-lived generation assets at a time when technologies and markets are rapidly evolving.
- Theorizing the Behavioral Dimension of Energy Consumption
In: Energy and Society Handbook
This chapter focuses on the well-documented misalignment between energy-related behaviors and the personal values of consumers, which has become a major source of angst among
policymakers. Despite widespread pro-environmental or green attitudes, consumers frequently purchase non-green alternatives. The chapter identifies 50 theoretical approaches that can be
divided almost equally into two types: those that emphasize beliefs, attitudes, and values; and those that also consider contextual factors and social norms. Three principles of intervention are recommended: provide credible and targeted information at points of decision; identify and address the key factors inhibiting and promoting the target behaviours in particular populations; and rigorously evaluate programes to provide credible estimates of impact and opportunities for improvements. The chapter recommends that research on the value-action gap be expanded beyond the traditional focus on individuals to include decision-making units such as households, boards of directors, commercial buying units, and government procurement groups.