| Assessing Transformation Pathways. In: Climate Change 2014: Mitigation of Climate Change. Contribution of Working Group III to the Fifth Assessment Report of the … LE Clarke, K Jiang, K Akimoto, M Babiker, GJ Blanford, K Fisher-Vanden, ... Pacific Northwest National Lab.(PNNL), Richland, WA (United States), 2015 | 1039* | 2015 |
| Net carbon uptake has increased through warming-induced changes in temperate forest phenology TF Keenan, J Gray, MA Friedl, M Toomey, G Bohrer, DY Hollinger, ... Nature Climate Change 4 (7), 598-604, 2014 | 832 | 2014 |
| Trade blocs World Bank The World Bank, 2000 | 588* | 2000 |
| Hidden costs of energy: unpriced consequences of energy production and use National Research Council, Policy, Global Affairs, Board on Science, ... National Academies Press, 2010 | 490 | 2010 |
| Amplification of future energy demand growth due to climate change BJ Van Ruijven, E De Cian, I Sue Wing Nature communications 10 (1), 2762, 2019 | 451 | 2019 |
| Computable general equilibrium models and their use in economy-wide policy analysis IS Wing Technical Note, Joint Program on the Science and Policy of Global Change, MIT, 2004 | 423 | 2004 |
| The MIT emissions prediction and policy analysis (EPPA) model: revisions, sensitivities, and comparisons of results MHM Babiker, JM Reilly, M Mayer, RS Eckaus, I Sue Wing, RC Hyman MIT Joint Program on the Science and Policy of Global Change, 2001 | 351 | 2001 |
| Explaining the declining energy intensity of the US economy IS Wing Resource and energy economics 30 (1), 21-49, 2008 | 273 | 2008 |
| The synthesis of bottom-up and top-down approaches to climate policy modeling: Electric power technologies and the cost of limiting US CO2 emissions IS Wing Energy Policy 34 (18), 3847-3869, 2006 | 218 | 2006 |
| The synthesis of bottom-up and top-down approaches to climate policy modeling: Electric power technology detail in a social accounting framework IS Wing Energy economics 30 (2), 547-573, 2008 | 215 | 2008 |
| Absolute versus intensity-based emission caps AD Ellerman, IS Wing Climate Policy 3 (sup2), S7-S20, 2003 | 184 | 2003 |
| Representing induced technological change in models for climate policy analysis IS Wing Energy Economics 28 (5-6), 539-562, 2006 | 183 | 2006 |
| Cities, traffic, and CO2: A multidecadal assessment of trends, drivers, and scaling relationships CK Gately, LR Hutyra, I Sue Wing Proceedings of the National Academy of Sciences 112 (16), 4999-5004, 2015 | 175 | 2015 |
| Increasing ambient temperature reduces emotional well-being C Noelke, M McGovern, DJ Corsi, MP Jimenez, A Stern, IS Wing, ... Environmental research 151, 124-129, 2016 | 172 | 2016 |
| Global energy consumption in a warming climate E De Cian, I Sue Wing Environmental and resource economics 72, 365-410, 2019 | 165* | 2019 |
| Urban emissions hotspots: Quantifying vehicle congestion and air pollution using mobile phone GPS data CK Gately, LR Hutyra, S Peterson, IS Wing Environmental pollution 229, 496-504, 2017 | 162 | 2017 |
| Economic consequences of pollinator declines: a synthesis DM Bauer, IS Wing Agricultural and Resource Economics Review 39 (3), 368-383, 2010 | 139 | 2010 |
| Induced technical change and the cost of climate policy I Sue Wing | 128 | 2003 |
| Adjustment time, capital malleability and policy cost HD Jacoby, IS Wing The Energy Journal 20 (1_suppl), 73-92, 1999 | 128 | 1999 |
| Toward a useful architecture for climate change negotiations HD Jacoby, R Schmalensee, I Sue Wing MIT Joint Program on the Science and Policy of Global Change, 1999 | 121 | 1999 |
Enrica De CianCa' Foscari Unversity of Venice, ItalyVerified email at unive.it
