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Material Flows and Stocks in the Urban Building Sector: A Case Study from Vienna for the Years 1990–2015

Author

Listed:
  • Jakob Lederer

    (Christian Doppler Laboratory for Anthropogenic Resources, Institute for Water Quality and Resource Management, TU Wien, Karlsplatz 13/226, 1040 Vienna, Austria
    Institute of Chemical, Environmental and Bioscience Engineering, TU Wien, Getreidemarkt 9/166-01, 1060 Vienna, Austria)

  • Andreas Gassner

    (Christian Doppler Laboratory for Anthropogenic Resources, Institute for Water Quality and Resource Management, TU Wien, Karlsplatz 13/226, 1040 Vienna, Austria)

  • Florian Keringer

    (Austrian Institute of Regional Studies (OIR GmbH), Franz-Josefs-Kai 27, 1010 Vienna, Austria)

  • Ursula Mollay

    (Austrian Institute of Regional Studies (OIR GmbH), Franz-Josefs-Kai 27, 1010 Vienna, Austria)

  • Christoph Schremmer

    (Austrian Institute of Regional Studies (OIR GmbH), Franz-Josefs-Kai 27, 1010 Vienna, Austria)

  • Johann Fellner

    (Christian Doppler Laboratory for Anthropogenic Resources, Institute for Water Quality and Resource Management, TU Wien, Karlsplatz 13/226, 1040 Vienna, Austria)

Abstract

Population growth in cities leads to high raw material consumption and greenhouse gas emissions. In temperate climates were heating of buildings is among the major contributors to greenhouse gases, thermal insulation of buildings became a standard in recent years. Both population growth and greenhouse gas mitigation may thus have some influence on the quantity and composition of building material stock in cities. By using the case study of Vienna, this influence is evaluated by calculating the stock of major building materials (concrete, bricks, mortar, and plaster, steel, wood, glass, mineral wool, and polystyrene) between the years 1990 and 2015. The results show a growth of the material stock from 274 kt in the year 1990 to 345 kt in the year 2015, resulting in a total increase of 26%. During the same period, the population grew by 22%. On a material level, the increase of thermal insulation materials like polystyrene and mineral wool by factors of 6.5 and 2.5 respectively were much higher than for other materials, indicating energy efficiency and greenhouse gas mitigation in the building construction sector. The displacement of brickwork by concrete as the most important construction material, however, is rather a response to population growth as concrete buildings can be raised faster. A question for the future is to which extent this change from brickwork to high carbon-intensive concrete countervails the achievements in greenhouse gas reduction by thermal insulation.

Suggested Citation

  • Jakob Lederer & Andreas Gassner & Florian Keringer & Ursula Mollay & Christoph Schremmer & Johann Fellner, 2019. "Material Flows and Stocks in the Urban Building Sector: A Case Study from Vienna for the Years 1990–2015," Sustainability, MDPI, vol. 12(1), pages 1-25, December.
    • Handle: RePEc:gam:jsusta:v:12:y:2019:i:1:p:300-:d:303416
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    References listed on IDEAS

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    1. Mingming Hu & Ester Van Der Voet & Gjalt Huppes, 2010. "Dynamic Material Flow Analysis for Strategic Construction and Demolition Waste Management in Beijing," Journal of Industrial Ecology, Yale University, vol. 14(3), pages 440-456, June.
    2. Christopher Kennedy & John Cuddihy & Joshua Engel‐Yan, 2007. "The Changing Metabolism of Cities," Journal of Industrial Ecology, Yale University, vol. 11(2), pages 43-59, April.
    3. Janet L. Reyna & Mikhail V. Chester, 2015. "The Growth of Urban Building Stock: Unintended Lock-in and Embedded Environmental Effects," Journal of Industrial Ecology, Yale University, vol. 19(4), pages 524-537, August.
    4. Xuemei Bai, 2007. "Industrial Ecology and the Global Impacts of Cities," Journal of Industrial Ecology, Yale University, vol. 11(2), pages 1-6, April.
    5. Phdungsilp, Aumnad, 2010. "Integrated energy and carbon modeling with a decision support system: Policy scenarios for low-carbon city development in Bangkok," Energy Policy, Elsevier, vol. 38(9), pages 4808-4817, September.
    6. Hasanbeigi, Ali & Price, Lynn & Lin, Elina, 2012. "Emerging energy-efficiency and CO2 emission-reduction technologies for cement and concrete production: A technical review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 16(8), pages 6220-6238.
    7. Dominik Wiedenhofer & Julia K. Steinberger & Nina Eisenmenger & Willi Haas, 2015. "Maintenance and Expansion: Modeling Material Stocks and Flows for Residential Buildings and Transportation Networks in the EU25," Journal of Industrial Ecology, Yale University, vol. 19(4), pages 538-551, August.
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