nach oben

Mitigation and Adaptation Strategies for Global Change

Erschienen in:

01.10.2012 | Original Article

CO₂-emission reduction in China’s residential building sector and contribution to the national climate change mitigation targets in 2020

verfasst von: Andreas Oberheitmann

Erschienen in: Mitigation and Adaptation Strategies for Global Change | Ausgabe 7/2012

Einloggen, um Zugang zu erhalten

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

Between 1980 and 2007, in the Chinese building sector in urban and rural areas, coal was mainly substituted with electricity and natural gas. Growing income will further increase energy consumption and CO₂-emissions in the building sector. Using an econometric model, disaggregated energy demand and related CO₂-emissions in the residential sector as well for the whole economy are estimated and forecasted until 2050. In 2009, the Chinese government pledged itself to reduce CO₂-intensity by 40%–45% in 2020 compared to 2005. Aim of this article is to assess to which extent the measures in the building sector in China can contribute to this target. Main results of the analysis are: (a) The primary energy source coal was mainly substituted by electricity generated with coal. Apart from convenience gains, the environmental advantages are questionable. (b) Between 2010 and 2050, energy demand in the building sector will grow by 2.0%–4.1% per annum leading to CO₂-emissions at least almost tripling from about 560 mill. tons in 2010 to about 1,500 mill. tons in 2050. (c) The energy efficiency gains in the building sector and other sectors of the Chinese economy, however, are not enough to fulfill the national CO₂-intensity targets. The reduction of the CO₂-intensity of GDP would be 37.2% in the BAU-scenario, and 31.9% in the LOW-scenario. Only in the HIGH-scenario (46.3%), the economy is growing efficient enough relative to the induced CO₂-emissions. The remaining CO2-emission reductions could be gained by additional promotion of renewable energies (mainly solar and geo-thermal) in the building sector.

Vorheriger Artikel Oil price scenarios and climate policy: welfare effects of including transportation in the EU emissions trading system

Nächster Artikel Natural and effective control of air pollution through plants- studies on a tree species: Holoptelea integrifolia L.

We thus use unit root tests, introduced by Dickey and Fuller (1979), in order to examine whether or not the time series of GDP per capita, primary energy consumption, heating degree days, as well as CO₂emissions behave like random walks. Our augmented DICKEY-FULLER (ADF) test results indicate that the unit-root or random-walk hypotheses can be safely rejected merely for heating degree days. While the unit-root hypotheses cannot be rejected for energy consumption and CO₂ emissions, their first differences appear to be stationary. In other words, these variables are integrated of order one. Only the first differences of GDP per capita may follow a random walk. Applying an ADF-test to the time series of the OLS-residuals indicates stationarity of the error terms. That means, the OLS estimations do not lead to spurious results such as the linear combination of the variables as given in energy consumption models (1–6) which appear to be co-integrated.

Barker T, Bashmakov I, Alharthi A, Amann M, Cifuentes L, Drexhage J, Duan M, Edenhofer O, Flannery B, Grubb M, Hoogwijk M, Ibitoye FI, Jepma CJ, Pizer WA, Yamaji K (2007) Mitigation from a cross-sectoral perspective. In: Metz B, Davidson OR, Bosch PR, Dave R, Meyer LA (eds) Climate Change 2007: Mitigation. Contribution of Working Group III to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge and New York

Cheng C, Pouffary S, Svenningsen N, Callaway M (2008) The Kyoto protocol, the clean development mechanism and the building and construction sector—a report for the UNEP Sustainable Buildings and Construction Initiative, United Nations Environment Programme, Paris, France. http://uneprisoe.org/CDMbuildings/CDMbuildings.pdf

De T’Serclaes P (2007) Financing energy efficient homes, existing policy responses to financial barriers: IEA Information Paper, International Energy Agency (IEA), OECD/IEA, Paris. http://www.iea.org/papers/2007/FinancialBarrierBuilding.pdf

Dickey DA, Fuller WA (1979) Distribution of the estimators for autoregressive time series with a unit root. J Am Stat Assoc 74:427–431

Figueres C, Philips M (2007) Scaling up demand-side energy efficiency improvements through programmatic CDM. Sustainable Development Network, World Bank

Hohenstein H (2011) Evaluation of energy saving technologies, systems and materials for the practical application of low carbon concepts in new buildings in China. Contribution to the Study “Carbon market in the new building sector in China—Programmatic-CDM, new sectoral approaches, development of a national trade platform”. Beijing, mimeo

IEA (2008) Energy efficiency requirements in building codes, energy efficiency policies for new buildings. IEA Information paper in support of the G8 Plan of Action. Paris. http://www.iea.org/g8/2008/Building_Codes.pdf

IEA (2011) Technology roadmap—energy-efficient buildings: heating and cooling equipment. Paris. http://www.iea.org/papers/2011/buildings_roadmap.pdf

Jaffe A, Stavins R (1994) The energy-efficiency gap. What does it mean? Energy Policy 22:804–810CrossRef

Levine M, Ürge-Vorsatz D, Blok K, Geng L, Harvey D, Lang S, Levermore G, Mongameli Mehlwana A, Mirasgedis S, Novikova A, Rilling J, Yoshino H (2007) Residential and commercial buildings, Climate Change 2007: Mitigation. In: Metz B et al (eds) Contribution of Working Group III to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge & New York

Li J (2008) Towards a low-carbon future in China’s building sector—a review of energy and climate models forecast. Energy Policy 36(5):1736–1747CrossRef

Ministry of City and Country Construction and Environmental Protection (1986) Thermal energy conservation design standard for new heating residential buildings (Dwelling Building with Heating System) JGJ 26–86. Beijing

Ministry of Construction (1986) Design code for energy saving of civil building (Residential Building with Heating System) JGJ 26–86. Beijing

Ministry of Construction (1995) Energy conservation design standard for new heating residential buildings (Residential Building with Heating System) JGJ 26–95. Beijing

Oberheitmann A, Frondel M (2006) The dark side of China’s increasing economic prosperity: Will energy consumption and global emissions rise drastically? In: Bleischwitz R, Budzinski O (eds) Environmental economics—institutions, competition, rationality. INFER Annual Conference 2004, Wuppertal, Germany. Berlin, pp 207–224

Oberheitmann A, Sternfeld E (2011) Global environmental governance, responsibility and China’s role in a new post-Kyoto regime. In: Harris PG (ed) China’s responsibility for climate change: Ethics, fairness and environmental policy. The Policy Press, pp 195–222

Richerzhagen C, von Frieling T, Hansen N, Minnaert A, Netzer N, Rußbild J (2008) Energy efficiency in buildings in China—policies, barriers and opportunities. Studies/Deutsches Institut für Entwicklungspolitik 41. Bonn. http://www.die-gdi.de/CMS-Homepage/openwebcms3.nsf/(ynDK_contentByKey)/ANES-7NJGTV/$FILE/Studies%2041.2008.pdf

State Statistical Bureau (diff. issues) China Energy Statistical Yearbook. Beijing

State Statistical Bureau (a) (diff. issues) China Statistical Yearbook. Beijing

UNEP (2009) Submission of the United Nations Environment Programme (UNEP) Sustainable Building Initiative (SBCI) to the Ad-Hoc Working Group on Further Commitments for Annex I Countries under the Kyoto Protocol (AWG-KP). http://www.unep.org/sbci/pdfs/UNEP_SBCI_submission_to_AWG_KP_rev1__2_.pdf.

Zhou N, McNeil MA, Fridley D, Lin J, Price L, de la Rue du Can S, Sathaye J, Levine M (2007) Energy use in China: sectoral trends and future outlook. LBNL, Energy Analysis Division. LBNL-61904. http://minotaur.lbl.gov/china.lbl.gov/sites/china.lbl.gov/files/LBNL61904.Energy_Use_in_China_Sectoral_Trends_and_Future_Outlook.2007.pdf

Zhou N, Levine MD, Price L (2010) Overview of current energy efficiency policies in China. Energy Policy 38(11):6439–6452CrossRef

Titel: CO2-emission reduction in China’s residential building sector and contribution to the national climate change mitigation targets in 2020
verfasst von: Andreas Oberheitmann
Publikationsdatum: 01.10.2012
Verlag: Springer Netherlands
Erschienen in: Mitigation and Adaptation Strategies for Global Change / Ausgabe 7/2012
Print ISSN: 1381-2386
Elektronische ISSN: 1573-1596
DOI: https://doi.org/10.1007/s11027-011-9343-5

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Weitere Artikel der Ausgabe 7/2012

Assessment of trophic change and its probable impact on tropical estuarine environment (the Kodungallur-Azhikode estuary, India)

Perceptions of climate change risks and resilient island planning in the Maldives

Natural and effective control of air pollution through plants- studies on a tree species: Holoptelea integrifolia L.

Oil price scenarios and climate policy: welfare effects of including transportation in the EU emissions trading system

Need for adaptation strategy against global sea level rise: an example from Saudi coast of Arabian gulf

Incorporating stakeholder decision support needs into an integrated regional Earth system model