Source: NASA, public domain image
References for the Debate on a Globally-administered Carbon Tax
Info extracted Litoscope 2.0 by SDR Lab @ UNU-MERIT
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Publication |
Web of Science Categories |
Keywords |
Research Field |
Keywords |
Khanna et al. (2011) ~4 CpY |
Biology |
GREENHOUSE-GAS EMISSIONS; COST REDUCTIONS; CORN-ETHANOL; ENERGY; ENVIRONMENT; MISCANTHUS; STANDARDS; RESPONSES; IMPACTS; MARKET |
Life Sciences & Biomedicine – Other Topics |
indirect land use change; economic models; environmental externalities |
Meunier et al. (2014) ~2.83 CpY |
Business; Economics; Environmental Studies |
BORDER ADJUSTMENT; ETS; COMPETITIVENESS; INDUSTRY; DESIGN |
Business & Economics; Environmental Sciences & Ecology |
Cap and trade; Output-based allocation; Subsidization of capacity; Climate policy; Carbon leakage; Competitiveness |
McEvoy and McGinty (2018) ~0.5 CpY |
Business; Economics; Environmental Studies |
STOCK POLLUTANT; UNCERTAINTY; QUANTITIES; PRICES |
Business & Economics; Environmental Sciences & Ecology |
Global public goods; Uniform emissions tax; International environmental agreements; Externalities |
van der Ploeg and Rezai (2017) ~1.67 CpY |
Business; Regional & Urban Planning |
CLIMATE-CHANGE; DAMAGE COSTS; SOCIAL COST; ECONOMICS |
Business & Economics; Public Administration |
Energy transition; Optimal carbon tax; Unburnable fossil fuel; Cumulative emissions; Oxford carbon cycle; Trend growth |
Fisher-Vanden et al. (2012) ~1.38 CpY |
Economics |
ENERGY |
Business & Economics |
Asia; Energy use; Carbon emissions; Global climate change; Computable general equilibrium; Technological change |
Davies et al. (2014) ~0.5 CpY |
Economics |
TAXATION; INCOME |
Business & Economics |
Carbon pricing; Gini; Poverty reduction; Millennium development goals |
Sheng et al. (2018) ~0 CpY |
Economics |
GREENHOUSE-GAS EMISSIONS; MARKET-BASED MEASURES; CARBON TAXES; CO2 EMISSIONS; POLICY; TRADE |
Business & Economics |
Bunker emissions charge; International maritime transport; Economic and trade impact; CGE model |
van Vuuren et al. (2009) ~1.64 CpY |
Economics; Energy & Fuels; Environmental Sciences; Environmental Studies |
TEMPERATURE INCREASE; AIR-POLLUTION; COSTS; SCENARIOS; TARGETS; EUROPE; MODEL |
Business & Economics; Energy & Fuels; Environmental Sciences & Ecology |
Climate policy; Global carbon tax; Broadening participation |
Andersson and Karpestam (2013) ~2.14 CpY |
Economics; Energy & Fuels; Environmental Sciences; Environmental Studies |
ENVIRONMENTAL KUZNETS CURVE; STRUCTURAL-CHANGE; BUSINESS CYCLES; DECOMPOSITION; CONSUMPTION; GROWTH; COUNTRIES; US; QUANTITIES; WAVELETS |
Business & Economics; Energy & Fuels; Environmental Sciences & Ecology |
Economic growth; CO2 emissions; Short and long run |
JAEGER (1995) ~0.16 CpY |
Economics; Energy & Fuels; Environmental Sciences; Environmental Studies |
TAXATION; EFFICIENCY; ECONOMICS |
Business & Economics; Energy & Fuels; Environmental Sciences & Ecology |
GLOBAL WARMING; CARBON TAX; EXCESS BURDEN; REVENUE RECYCLING |
Rezai and Van der Ploeg (2016) ~2.5 CpY |
Economics; Environmental Studies |
CLIMATE-CHANGE; SOCIAL COST; FOSSIL-FUEL; RISK; MITIGATION; FRAMEWORK; IMPACTS |
Business & Economics; Environmental Sciences & Ecology |
Alternative climate damage specifications; Growth; Intergenerational inequality aversion; Optimal carbon tax; Simple rule; Stranded assets; Transition times; Welfare losses |
Verbruggen (2011) ~0.56 CpY |
Economics; Environmental Studies; Law; Political Science |
ECONOMIC-POLICY; GOVERNANCE; INNOVATION; PROFITS; KYOTO; POWER |
Business & Economics; Environmental Sciences & Ecology; Government & Law |
Equity; Climate policy design principles; Diversity |
Gu and Wang (2019) ~1 CpY |
Economics; Management; Mathematics, Interdisciplinary Applications |
MODEL; TRADE |
Business & Economics; Mathematics |
Limiting carbon tax; Integrated assessment model; Tax revenue distribution; R&D investment; Process technology progress; Pareto improvement |
Zhang et al. (2014) ~4 CpY |
Energy & Fuels; Engineering, Chemical |
ELECTRICITY-GENERATION; POWER; SECTOR; OPTIONS; SYSTEMS; FUTURE; MODEL; ASIA |
Energy & Fuels; Engineering |
Energy technologies; Carbon emission mitigation; China |
Klimenko et al. (1999) ~0.19 CpY |
Energy & Fuels; Engineering, Chemical |
Energy & Fuels; Engineering |
||
Hof et al. (2011) ~2 CpY |
Environmental Sciences |
COUNTRIES; COSTS |
Environmental Sciences & Ecology |
Climate financing; Climate policy; Adaptation costs; Carbon market; Copenhagen Accord |
De Cian et al. (2016) ~0.5 CpY |
Environmental Sciences; Meteorology & Atmospheric Sciences |
TEMPERATURE; WORLD |
Environmental Sciences & Ecology; Meteorology & Atmospheric Sciences |
adaptation; mitigation; burden sharing; climate policy; integrated assessments |
Deetman et al. (2015) ~1.6 CpY |
Environmental Studies; Public Administration |
ENERGY; POLICY |
Environmental Sciences & Ecology; Public Administration |
bottom-up; energy modelling; mitigation scenarios |
Engstrom et al. (2017) ~0.33 CpY |
Geosciences, Multidisciplinary |
AGRICULTURAL LAND; CO2; MODEL; UNCERTAINTIES; SIMULATIONS; PROJECTIONS; ECOSYSTEMS; POTENTIALS; MANAGEMENT; SCENARIOS |
Geology |
|
Jensen et al. (2019) ~0 CpY |
Green & Sustainable Science & Technology; Environmental Sciences; Environmental Studies |
GREENHOUSE-GAS EMISSIONS; CLIMATE-CHANGE; SEQUESTRATION; SCENARIOS; DYNAMICS; POLICIES |
Science & Technology – Other Topics; Environmental Sciences & Ecology |
Paris Agreement; climate change mitigation; agricultural sector; market outlook; Aglink-Cosimo |
Carattini et al. (2019) ~0 CpY |
Multidisciplinary Sciences |
Science & Technology – Other Topics |
||
Fells (2002) ~0.22 CpY |
Thermodynamics; Engineering, Mechanical |
Thermodynamics; Engineering |
energy policy; renewable; security of supply; carbon emissions; nuclear fossil fuel |
Augmented Alphabetical Reference List with Citations Received per Year info
-17_CpY:2.14 Andersson, FNG. & Karpestam, P. (2013). CO2 emissions and economic activity: Short- and long-run economic determinants of scale, energy intensity and carbon intensity. ENERGY POLICY , 61 (), 1285- 1294. 10.1016/j.enpol.2013.06.004
-0_CpY:0 Carattini, S. , Kallbekken, S & Orlov, A. (2019). How to win public support for a global carbon tax. NATURE , 565 (7739), 289- 291. 10.1038/d41586-019-00124-x
-3_CpY:0.5 Davies, JB. , Shi, XJ & Whalley, J. (2014). The possibilities for global inequality and poverty reduction using revenues from global carbon pricing. JOURNAL OF ECONOMIC INEQUALITY , 12 (3), 363- 391. 10.1007/s10888-013-9259-2
-2_CpY:0.5 De Cian, E. , Hof, AF. , Marangoni, G. , Tavoni, M & van Vuuren, DP. (2016). Alleviating inequality in climate policy costs: an integrated perspective on mitigation, damage and adaptation. ENVIRONMENTAL RESEARCH LETTERS , 11 (7), – 0. 10.1088/1748-9326/11/7/074015
-8_CpY:1.6 Deetman, S. , Hof, AF & van Vuuren, DP. (2015). Deep CO2 emission reductions in a global bottom-up model approach. CLIMATE POLICY , 15 (2), 253- 271. 10.1080/14693062.2014.912980
-1_CpY:0.33 Engstrom, K. , Lindeskog, M. , Olin, S. , Hassler, J & Smith, B. (2017). Impacts of climate mitigation strategies in the energy sector on global land use and carbon balance. EARTH SYSTEM DYNAMICS , 8 (3), 773- 799. 10.5194/esd-8-773-2017
-4_CpY:0.22 Fells, I. (2002). Clean and secure energy for the twenty-first century. PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART A-JOURNAL OF POWER AND ENERGY , 216 (A4), 291- 294. 10.1243/09576500260251138
-11_CpY:1.38 Fisher-Vanden, K. , Schu, K. , Wing, IS & Calvin, K. (2012). Decomposing the impact of alternative technology sets on future carbon emissions growth. ENERGY ECONOMICS , 34 (), S359- S365. 10.1016/j.eneco.2012.07.021
-1_CpY:1 Gu, GX. & Wang, Z. (2019). The Limit of Global Carbon Tax and its Climatic and Economic Effects. COMPUTATIONAL ECONOMICS , 53 (1), 169- 189. 10.1007/s10614-017-9735-z
-19_CpY:2 Hof, AF. , den Elzen, MGJ & Beltran, AM. (2011). Predictability, equitability and adequacy of post-2012 international climate financing proposals. ENVIRONMENTAL SCIENCE & POLICY , 14 (6), 615- 627. 10.1016/j.envsci.2011.05.006
-4_CpY:0.16 JAEGER, WK. (1995). THE WELFARE COST OF A GLOBAL CARBON TAX WHEN TAX REVENUES ARE RECYCLED. RESOURCE AND ENERGY ECONOMICS , 17 (1), 47- 67. 10.1016/0928-7655(94)00026-G
-0_CpY:0 Jensen, H. , Dominguez, IP. , Fellmann, T. , Lirette, P. , Hristov, J & Philippidis, G. (2019). Economic Impacts of a Low Carbon Economy on Global Agriculture: The Bumpy Road to Paris. SUSTAINABILITY , 11 (8), – 0. 10.3390/su11082349
-36_CpY:4 Khanna, M. , Crago, CL & Black, M. (2011). Can biofuels be a solution to climate change? The implications of land use change-related emissions for policy. INTERFACE FOCUS , 1 (2), 233- 247. 10.1098/rsfs.2010.0016
-4_CpY:0.19 Klimenko, VV. , Mikushina, OV & Tereshin, AG. (1999). Do we really need a carbon tax?. APPLIED ENERGY , 64 (43469), 311- 316. 10.1016/S0306-2619(99)00104-X
-1_CpY:0.5 McEvoy, DM. & McGinty, M. (2018). Negotiating a uniform emissions tax in international environmental agreements. JOURNAL OF ENVIRONMENTAL ECONOMICS AND MANAGEMENT , 90 (), 217- 231. 10.1016/j.jeem.2018.06.001
-17_CpY:2.83 Meunier, G. , Ponssard, JP & Quirion, P. (2014). Carbon leakage and capacity-based allocations: Is the EU right?. JOURNAL OF ENVIRONMENTAL ECONOMICS AND MANAGEMENT , 68 (2), 262- 279. 10.1016/j.jeem.2014.07.002
-10_CpY:2.5 Rezai, A. & Van der Ploeg, F. (2016). Intergenerational Inequality Aversion, Growth, and the Role of Damages: Occam’s Rule for the Global Carbon Tax. JOURNAL OF THE ASSOCIATION OF ENVIRONMENTAL AND RESOURCE ECONOMISTS , 3 (2), 493- 522. 10.1086/686294
-0_CpY:0 Sheng, Y. , Shi, XP & Su, B. (2018). Re-analyzing the economic impact of a global bunker emissions charge. ENERGY ECONOMICS , 74 (), 107- 119. 10.1016/j.eneco.2018.05.035
-5_CpY:1.67 van der Ploeg, F. & Rezai, A. (2017). Cumulative emissions, unburnable fossil fuel, and the optimal carbon tax. TECHNOLOGICAL FORECASTING AND SOCIAL CHANGE , 116 (), 216- 222. 10.1016/j.techfore.2016.10.016
-18_CpY:1.64 van Vuuren, DP. , den Elzen, MGJ. , van Vliet, J. , Kram, T. , Lucas, P & Isaac, M. (2009). Comparison of different climate regimes: the impact of broadening participation. ENERGY POLICY , 37 (12), 5351- 5362. 10.1016/j.enpol.2009.07.058
-5_CpY:0.56 Verbruggen, A. (2011). Preparing the design of robust climate policy architectures. INTERNATIONAL ENVIRONMENTAL AGREEMENTS-POLITICS LAW AND ECONOMICS , 11 (4), 275- 295. 10.1007/s10784-010-9130-x
-24_CpY:4 Zhang, SW. , Bauer, N. , Luderer, G & Kriegler, E. (2014). Role of technologies in energy-related CO2 mitigation in China within a climate-protection world: A scenarios analysis using REMIND. APPLIED ENERGY , 115 (), 445- 455. 10.1016/j.apenergy.2013.10.039
Industry Links: (Product and services):
- http://www.climateaction100.org/
- https://www.euronews.com/2018/05/08/meet-the-artist-raising-awareness-about-google-s-carbon-footprint
- https://www.theguardian.com/environment/2011/sep/08/google-carbon-footprint
- https://www.cnbc.com/2019/03/08/jeff-bezos-to-end-secrecy-over-amazons-role-in-carbon-emissions.html
- https://qz.com/1267709/every-google-search-results-in-co2-emissions-this-real-time-dataviz-shows-how-much/
Updated: 26 June 2019
