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  • ddc:600  (3)
  • Electronic books.  (1)
  • 01. Atmosphere::01.01. Atmosphere::01.01.08. Instruments and techniques
  • 03. Hydrosphere::03.01. General::03.01.07. Physical and biogeochemical interactions
  • Anthropology.
  • Berlin : Dt. Ges. für Techn. Zusammenarbeit  (2)
  • Oxford :Taylor & Francis Group,  (1)
  • Wuppertal : Wuppertal Institute for Climate, Environment and Energy  (1)
  • Stockholm : European Council for an Energy Efficient Economy
  • English  (4)
  • 2020-2023
  • 2015-2019  (4)
  • 2017  (4)
Document type
Keywords
  • ddc:600  (3)
  • Electronic books.  (1)
  • 01. Atmosphere::01.01. Atmosphere::01.01.08. Instruments and techniques
  • 03. Hydrosphere::03.01. General::03.01.07. Physical and biogeochemical interactions
  • Anthropology.
    • +
Publisher
Language
  • English  (4)
Years
  • 2020-2023
  • 2015-2019  (4)
Year
  • 1
    Online Resource
    Online Resource
    Climate Change. (2017)
    Oxford :Taylor & Francis Group,
    Details
    Keywords: Climatic changes-Economic aspects. ; Electronic books.
    Description / Table of Contents: Within this volume the contributors have included a wide range of journal essays that consider the impact of climate change on specific sectors; goods and services; the costs and benefits of greenhouse gas (GHG) mitigation; and policy design for mitigation, including both domestic instruments and issues related to international agreements.
    Type of Medium: Online Resource
    Pages: 1 online resource (583 pages)
    Edition: 1st ed.
    ISBN: 9781351161596
    URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=5227391
    DDC: 363.738/74
    Language: English
    Note: Cover -- Half Title -- Series Title -- Title -- Copyright -- Contents -- Acknowledgements -- Series Preface -- Introduction -- PART I CLIMATE CHANGE AND ITS IMPACTS -- 1 John Houghton (2001), 'The Science of Global Warming', Interdisciplinary Science Reviews, 26, pp. 247-57. -- 2 Brent Sohngen and Robert Mendelsohn (1998), 'Valuing the Impact of Large-Scale Ecological Change in a Market: The Effect of Climate Change on U.S. Timber', American Economic Review, 88, pp. 686-710. -- 3 Kenneth D. Frederick and David C. Major (1997), 'Climate Change and Water Resources', Climatic Change, 37, pp. 7-23. -- 4 Gary Yohe and Michael Schlesinger (2002), 'The Economic Geography of the Impacts of Climate Change', Journal of Economic Geography, 2, pp. 311-41. -- 5 Allan D. Brunner (2002), 'El Nino and World Primary Commodity Prices: Warm Water or Hot Air?', Review of Economics and Statistics, 84, pp. 176-83. -- 6 Robert Mendelsohn, William D. Nordhaus and Daigee Shaw (1994), 'The Impact of Global Warming on Agriculture: A Ricardian Analysis', American Economic Review, 84, pp. 753-71. -- 7 John Quiggin and John K. Horowitz (1999), 'The Impact of Global Warming on Agriculture: A Ricardian Analysis: Comment', American Economic Review, 89, pp. 1044-45. -- 8 Robert Mendelsohn and William Nordhaus (1999), 'The Impact of Global Warming on Agriculture: A Ricardian Analysis: Reply', American Economic Review, 89, pp. 1046-48. -- 9 Roy Darwin (1999), 'The Impact of Global Warming on Agriculture: A Ricardian Analysis: Comment', American Economic Review, 89, pp. 1049-52. -- 10 Robert Mendelsohn and William Nordhaus (1999), 'The Impact of Global Warming on Agriculture: A Ricardian Analysis: Reply', American Economic Review, 89, pp. 1053-55. -- PART II EVALUATING THE COSTS AND BENEFITS OF CLIMATE CHANGE MITIGATION. , 11 William D. Nordhaus (1993), 'Rolling the "DICE": An Optimal Transition Path for Controlling Greenhouse Gases', Resource and Energy Economics, 15, pp. 27-50. -- 12 Richard S.J. Tol (1999), 'The Marginal Costs of Greenhouse Gas Emissions', Energy Journal, 20, pp. 61-81. -- 13 Tim Roughgarden and Stephen H. Schneider (1999), 'Climate Change Policy: Quantifying Uncertainties for Damages and Optimal Carbon Taxes', Energy Policy, 27, pp. 415-29. -- 14 Lawrence H. Goulder and Koshy Mathai (2000), 'Optimal C02 Abatement in the Presence of Induced Technological Change', Journal of Environmental Economics and Management, 39, pp. 1-38. -- 15 Charles D. Kolstad (1996), 'Learning and Stock Effects in Environmental Regulation: The Case of Greenhouse Gas Emissions', Journal of Environmental Economics and Management, 31, pp. 1-18. -- 16 Christian Azar and Thomas Sterner (1996), 'Discounting and Distributional Considerations in the Context of Global Warming', Ecological Economics, 19, pp. 169-84. -- 17 Richard B. Howarth (2000), 'Climate Change and the Representative Agent', Environmental and Resource Economics, 15, pp. 135-48. -- 18 Thomas C. Schelling (1995), 'Intergenerational Discounting', Energy Policy, 23, pp. 395-401. -- 19 T.M.L. Wigley, R. Richels and J.A. Edmonds (1996), 'Economic and Environmental Choices in the Stabilization of Atmospheric C02 Concentrations', Nature, 379, pp. 240-43. -- 20 Zhongxiang Zhang (2000), 'Decoupling China's Carbon Emissions Increase from Economic Growth: An Economic Analysis and Policy Implications', World Development, 28, pp. 739-52. -- 21 Robert C. Hyman, John M. Reilly, Mustafa H. Babiker, Ardoin De Masin and Henry D. Jacoby (2003), 'Modeling N on-C02 Greenhouse Gas Abatement', Environmental Modeling and Assessment, 8, pp. 175-86. , 22 Richard G. Newell and Robert N. Stavins (2000), 'Climate Change and Forest Sinks: Factors Affecting the Costs of Carbon Sequestration', Journal of Environmental Economics and Management, 40, pp. 211-35. -- 23 Andrew J. Plantinga, Thomas Mauldin and Douglas J. Miller (1999), 'An Econometric Analysis of the Costs of Sequestering Carbon in Forests', American Journal of Agricultural Economics', 81, pp. 812-24. -- PART III POLICY DESIGN FOR GHG MITIGATION -- 24 Ian W.H. Parry and Roberton C. Williams III (1999), 'A Second-Best Evaluation of Eight Policy Instruments to Reduce Carbon Emissions', Resource and Energy Economics, 21, pp. 347-73. -- 25 William A. Pizer (2002), 'Combining Price and Quantity Controls to Mitigate Global Climate Change', Journal of Public Economics, 85, pp. 409-34. -- 26 Michael Grubb (1997), 'Technologies, Energy Systems and the Timing of C02 Emissions Abatement: An Overview of Economic Issues', Energy Policy, 25, pp. 159-72. -- 27 Adam B. Jaffe and Robert N. Stavins (1994), 'Energy-Efficiency Investments and Public Policy', Energy Journal, 15, pp. 43-65. -- 28 P.R. Shukla (1996), 'The Modelling of Policy Options for Greenhouse Gas Mitigation in India', Ambio, 25, pp. 240-48. -- 29 Scott Barrett (1998), 'Political Economy of the Kyoto Protocol', Oxford Review of Economic Policy, 14, pp. 20-39. -- 30 Adam Rose, Brandt Stevens, Jae Edmonds and Marshall Wise (1998),' International Equity and Differentiation in Global Warming Policy: An Application to Tradeable Emission Permits', Environmental and Resource Economics, 12, pp. 25-51. -- 31 Zili Yang (1999), 'Should the North Make Unilateral Technology Transfers to the South? North-South Cooperation and Conflicts in Responses to Global Climate Change', Resource and Energy Economics, 21, pp. 67-87. , 32 Mustafa Babiker, John M. Reilly and Henry D. Jacoby (2000), 'The Kyoto Protocol and Developing Countries', Energy Policy, 28, pp. 525-36. -- Name Index.
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  • 2
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    Decoupling energy and resource use from growth in the Indian construction sector : a baseline study (2017)
    Berlin : Dt. Ges. für Techn. Zusammenarbeit
    Details
    Publication Date: 2022-02-18
    Description: India is currently at a crucial juncture where it is aiming for economic growth to meet the basic needs of its 1.2 billion people. However, so far this growth has resulted in energy shortages and the increasing use of limited resources. This policy brief series is about decoupling, i.e. improving efficiency to reduce the resources and energy needed for this growth and meet the country's increasing development needs. The construction sector is highly resource and energy intensive; it is therefore imperative that it moves towards a path of environmental sustainability. This transition is likely to be achieved by decoupling both resource and energy use from the sector's growth. Decision-makers in the sector will play a crucial role in achieving this. The aim of this policy brief series is to inform decision-makers in India at central government and state level about the current status of research, policy and institutions in the Indian construction sector and to identify key drivers and barriers. Finally, practical recommendations will be made for decision-makers about how to promote decoupling of resource and energy use from growth in the construction sector. Policy brief 1 focuses on the baseline for decoupling in the Indian construction sector. The study draws attention to the existing scenario in terms of key policies, research and institutions linked to resources and energy in the sector.
    Keywords: ddc:600
    Repository Name: Wuppertal Institut für Klima, Umwelt, Energie
    Language: English
    Type: report , doc-type:report
    Format: application/pdf
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  • 3
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    Decoupling energy and resource use from growth in the Indian construction sector : a potential analysis study (2017)
    Berlin : Dt. Ges. für Techn. Zusammenarbeit
    Details
    Publication Date: 2022-02-18
    Description: India is currently at a crucial juncture where it is aiming for economic growth to meet the basic needs of its 1.2 billion people. However, so far this growth has resulted in energy shortages and the increasing use of limited resources. This policy brief series is about decoupling, i.e. improving efficiency to reduce the resources and energy needed for this growth and meet the country's increasing development needs. The construction sector is highly resource and energy intensive; it is therefore imperative that it moves towards a path of environmental sustainability. This transition is likely to be achieved by decoupling both resource and energy use from the sector's growth. Decision-makers in the sector will play a crucial role in achieving this. The aim of this policy brief series is to inform decision-makers in India at central government and state level about the current status of research, policy and institutions in the Indian construction sector and to identify key drivers and barriers. Finally, practical recommendations will be made for decision-makers about how to promote decoupling of resource and energy use from growth in the construction sector. Policy brief 2 focuses on analysing the potential for decoupling in the Indian buildings and construction sector. Primary and secondary research was conducted to identify the factors that influence decoupling. Subsequently, a framework was established to make it possible to measure the nature and extent of decoupling that is possible within the existing policy environment. Furthermore, gaps, drivers and barriers have been identified which could enable a potential analysis study on decoupling to be carried out. In addition, examples of good practice from Germany and other European countries have been studied with a view to learning lessons that can help to bridge the current gaps in India.
    Keywords: ddc:600
    Repository Name: Wuppertal Institut für Klima, Umwelt, Energie
    Language: English
    Type: report , doc-type:report
    Format: application/pdf
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  • 4
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    Decarbonization pathways for the industrial cluster of the Port of Rotterdam : final report (2017)
    Wuppertal : Wuppertal Institute for Climate, Environment and Energy
    Details
    Publication Date: 2022-02-18
    Description: On behalf of the Port of Rotterdam Authority, the Wuppertal Institute developed three possible pathways for a decarbonised port of Rotterdam until 2050. The port area is home to about 80 per cent of the Netherlands' petrochemical industry and significant power plant capacities. Consequently, the port of Rotterdam has the potential of being an international leader for the global energy transition, playing an important role when it comes to reducing CO2 emissions in order to deliver on the EU's long-term climate goals. The three decarbonisation scenarios all built on the increasing use of renewables (wind and solar power) and the adoption of the best available technologies (efficiency). The analysis focuses on power plants, refineries and the chemical industry, which together are responsible for more than 90 per cent of the port area's current CO2 emissions. The decarbonisation scenarios describe how CO2 emissions could be reduced by 75 to 98 per cent in 2050 (compared to 2015). Depending on the scenario, different mitigation strategies are relied upon, including electrification, closure of carbon cycles or carbon capture and storage (CCS). The study includes recommendations for local companies, the Port Authority as well as policy makers. In addition, the study includes a reference scenario, which makes it clear that a "business as usual" mentality will fall well short of contributing adequately to the EU's long-term climate goals.
    Keywords: ddc:600
    Repository Name: Wuppertal Institut für Klima, Umwelt, Energie
    Language: English
    Type: report , doc-type:report
    Format: application/pdf
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