Combining climate, economic, and social policy builds public support for climate action in the US Contact online >>
Combining climate, economic, and social policy builds public support for climate action in the US
Bergquist, Parrish, Mildenberger, Matto, and Stokes, Leah C. (2020). “Combining climate, economic, and social policy builds public support for climate action in the US.” IOP Publishing Ltd, Environmental Research Letters, Volume 15, Number 5.
Levinson, Arik & Sager, Lutz. (2020). “Who Values Future Energy Savings? Evidence from American Drivers.” National Bureau of Economic Research, Working Paper, Working Paper Series, 28219.
Estimating the effect of air pollution on road safety using atmospheric temperature inversions
Sager, Lutz. (2019). “Estimating the effect of air pollution on road safety using atmospheric temperature inversions.” Journal of Environmental Economics and Management, Vol. 98.
Income inequality and carbon consumption: Evidence from Environmental Engel curve
Sager, Lutz. (2019). “Income inequality and carbon consumption: Evidence from Environmental Engel curve.” Energy Economics, Vol. 84, Supplement 1.
Does Global Warming Increase Public Concern about Climate Change?
Bergquist, Parrish & Warshaw, Christopher. (2019). “Does Global Warming Increase Public Concern about Climate Change?” The Journal of Politics, Volume 81, Number 2.
Community-Based Assessments of Adaptation and Equity
Foster, S., Leichenko, R. Nguyen, K.H., Blake, R. Kunreuther, H., Madajewicz, M., Petkova, E.P, Zimmerman, R., Corbin-Mark, C., Yeampierre, E., Tovar, A., Herrera, C. & Ravenborg, D. (2019). “Community-Based Assessments of Adaptation and Equity.” Annals of the New York Academy of Sciences, Vol. 1439, pp. 126-173.
Resilience Strategies for Critical Infrastructures and Their Interdependencies
Foster, Sheila R., Zimmerman, Rae., González, Jorge. E., Jacob, Klaus., Kunreuther, Howard., Petkova, Elisaveta P. & Tollerson, Ernest. (2019). “Resilience Strategies for Critical Infrastructures and Their Interdependencies.” Annals of the New York Academy of Sciences, Vol. 1439, pp. 174-229.
Ostrom in the City: Design Principles and Practices for the Urban Commons
Foster, Sheila R. & Iaione, Christian. (2019). “Ostrom in the City: Design Principles and Practices for the Urban Commons.” Routledge Handbook of the Study of the Commons, pp. 235-255.
Controlling the Regulators: How Party Control of Government Shapes Environmental Regulation in the 21st Century
Berquist, Parrish. (2018). “Controlling the Regulators: How Party Control of Government Shapes Environmental Regulation in the 21st Century.” MIT .
Backyard Voices: How Sense of Place Shapes Views of Large-Scale Energy Transmission Infrastructure
Bergquist, Parrish., Ansolabahere, Stephen., Carley, Sanya. & Konisky, David. (2018). “Backyard Voices: How Sense of Place Shapes Views of Large-Scale Energy Transmission Infrastructure.” MIT .
Storylines: an alternative approach to representing uncertainty in physical aspects of climate change
Shepherd, Theodore G., Boyd, Emily, Calel, Raphael A., Chapman, Sandra C., Dessai, Suraje, Dima-West, Ioana M., Fowler, Hayley J., James, Rachel, Maraun, Douglas, Martius, Olivia, Senior, Catherine A., Sobel, Adam H., Stainforth, David A., Tett, Simon F. B., Trenberth, Kevin E., van den Hurk, Bart J. J. M., Watkins, Nicholas W., Wilby, Robert L. & Zenghelis, Dimitri A. (2018) “Storylines: an alternative approach to representing uncertainty in physical aspects of climate change.” pp. 555-571.
Adopt or Innovate: Understanding Technological Responses to Cap-and-Trade
Calel, Raphael. (2018). “Adopt or Innovate: Understanding Technological Responses to Cap-and-Trade.” CESifo Working Paper Series.
The Elusive Quest for Additionality
Carter, Paddy., Van de Sijpe, Nicolas. & Calel, Raphael. (2018). “The Elusive Quest for Additionality.” Center for Global Development.
Calel, Raphael & Stainforth, David A. (2017) “On the Physics of Three Integrated Assessment Models.” Bulletin of the American Meteorological Society, pp. 1199-1216.
Environmental Policy and Directed Technological Change: Evidence from the European Carbon Market
Calel, Raphael & Dechezleprêtre, Antoine. (2016). “Environmental Policy and Directed Technological Change: Evidence from the European Carbon Market.” The Review of Economics and Statistics (2016) 98 (1): 173–191.
From the Ground Up: Environmental Racism and the Rise of the Environmental Justice Movement
Cole, Luke W. & Foster, Sheila R. (2000). “From the Ground Up: Environmental Racism and the Rise of the Environmental Justice Movement.” NYU Press.
Georgetown Energy Partners is modernizing the university''s energy and water infrastructure – contributing to more reliable, efficient and sustainable operations. Below are a few feature projects around campus. Check back here often as new initiatives are added.
At the historic center of campus, Georgetown Energy Partners is replacing more than a mile of aging pipes and installing infrastructure for a more sustainable campus heating network.Read More ›
Almost every existing light on the Hilltop and Capitol campuses – more than 70,000 fixtures – is being upgraded to energy efficient light-emitting diodes (LEDs), which use half the energy of standard fluorescent lights and provide better lighting. This upgrade is estimated to reduce the university''s carbon footprint by over 1,700 tons of CO2 annually.
The BESO Program is a campus-wide initiative to upgrade heating, ventilation, and air conditioning (HVAC) equipment in facilities. The efforts typically permit better control of building temperature (cooling/heating), airflow, and efficient operation of major energy-using equipment. Heat recovery chillers will facilitate a dramatic reduction in natural gas usage attributable to each building.
As part of our ongoing efforts to modernize our campus energy systems, Georgetown Energy Partners will replace critical underground infrastructure supporting Georgetown''s central heating and cooling plant along West Road this fall.
Steam is piped around campus at a very high temperature and is slightly corrosive. Over time, the distribution system requires repairs to prevent leaks and deterioration of surrounding infrastructure. To address this, manholes are being repaired, condensate receiver pumps are being replaced, and steam traps are being enhanced.
What gets metered gets measured and what gets measured gets managed. The installation of real-time meters for energy and water consumption in campus buildings will allow Georgetown to better analyze and assess its usage and reduction targets. The meters will also facilitate a publicly available dashboard to track Georgetown''s progress to reduce its greenhouse gas emissions, and foster smart use of energy in residence halls and academic buildings.
The steam-line infrastructure under and near Cooper Field was nearing the end of its life. Modernizing the steam lines has reduced leakage and improved energy efficiency. The new field is composed of innovative materials, including pads that make the field safer for the athletes.
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