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Sustainability Impacts of Wood- and Concrete-Based Frame Buildings

Author

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  • Edgaras Linkevičius

    (Faculty of Forest Sciences and Ecology, Agriculture Academy, Vytautas Magnus University, Studentų 13, Akademija, LT-53362 Kaunas, Lithuania)

  • Povilas Žemaitis

    (Lithuanian Research Centre for Agriculture and Forestry, Instituto al. 1, Akademija, LT-58344 Kėdainiai, Lithuania)

  • Marius Aleinikovas

    (Lithuanian Research Centre for Agriculture and Forestry, Instituto al. 1, Akademija, LT-58344 Kėdainiai, Lithuania)

Abstract

The European Commission adopted a long-term strategic vision aiming for climate neutrality by 2050. Lithuania ratified the Paris agreement, making a binding commitment to cut its 1990 baseline GHG emissions by 40% in all sectors of its economy by 2030. In Lithuania, the main construction material is cement, even though Lithuania has a strong wood-based industry and abundant timber resources. Despite this, approximately twenty percent of the annual roundwood production from Lithuanian forests is exported, as well as other final wood products that could be used in the local construction sector. To highlight the potential that timber frame construction holds for carbon sequestration efforts, timber and concrete buildings were directly compared and quantified in terms of sustainability across their production value chains. Here the concept of “exemplary buildings” was avoided, instead a “traditional building” design was opted for, and two- and five-floor public buildings were selected. In this study, eleven indicators were selected to compare the sustainability impacts of wood-based and concrete-based construction materials, using a decision support tool ToSIA (a tool for sustainability impact assessment). Findings revealed the potential of glue-laminated timber (GLT) frames as a more sustainable alternative to precast reinforced concrete (PRC) in the construction of public low-rise buildings in Lithuania, and they showed great promise in reducing emissions and increasing the sequestration of CO 2 . An analysis of environmental and social indicators shows that the replacement of PRC frames with GLT frames in the construction of low-rise public buildings would lead to reduced environmental impacts, alongside a range of positive social impacts.

Suggested Citation

  • Edgaras Linkevičius & Povilas Žemaitis & Marius Aleinikovas, 2023. "Sustainability Impacts of Wood- and Concrete-Based Frame Buildings," Sustainability, MDPI, vol. 15(2), pages 1-19, January.
    • Handle: RePEc:gam:jsusta:v:15:y:2023:i:2:p:1560-:d:1034899
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    References listed on IDEAS

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    1. Gustavsson, L. & Nguyen, T. & Sathre, R. & Tettey, U.Y.A., 2021. "Climate effects of forestry and substitution of concrete buildings and fossil energy," Renewable and Sustainable Energy Reviews, Elsevier, vol. 136(C).
    2. Leif Gustavsson & Kim Pingoud & Roger Sathre, 2006. "Carbon Dioxide Balance of Wood Substitution: Comparing Concrete- and Wood-Framed Buildings," Mitigation and Adaptation Strategies for Global Change, Springer, vol. 11(3), pages 667-691, May.
    3. Bruno, Roberto & Bevilacqua, Piero & Cuconati, Teresa & Arcuri, Natale, 2019. "Energy evaluations of an innovative multi-storey wooden near Zero Energy Building designed for Mediterranean areas," Applied Energy, Elsevier, vol. 238(C), pages 929-941.
    4. Minunno, Roberto & O'Grady, Timothy & Morrison, Gregory M. & Gruner, Richard L., 2021. "Investigating the embodied energy and carbon of buildings: A systematic literature review and meta-analysis of life cycle assessments," Renewable and Sustainable Energy Reviews, Elsevier, vol. 143(C).
    5. McIntosh, Alison J. & Cockburn-Wootten, Cheryl, 2016. "Using Ketso for engaged tourism scholarship," Annals of Tourism Research, Elsevier, vol. 56(C), pages 148-151.
    6. Dodoo, Ambrose & Gustavsson, Leif & Sathre, Roger, 2009. "Carbon implications of end-of-life management of building materials," Resources, Conservation & Recycling, Elsevier, vol. 53(5), pages 276-286.
    7. Gustavsson, Leif & Haus, Sylvia & Lundblad, Mattias & Lundström, Anders & Ortiz, Carina A. & Sathre, Roger & Truong, Nguyen Le & Wikberg, Per-Erik, 2017. "Climate change effects of forestry and substitution of carbon-intensive materials and fossil fuels," Renewable and Sustainable Energy Reviews, Elsevier, vol. 67(C), pages 612-624.
    8. Toivonen, Ritva & Lilja, Anna & Vihemäki, Heini & Toppinen, Anne, 2021. "Future export markets of industrial wood construction – A qualitative backcasting study," Forest Policy and Economics, Elsevier, vol. 128(C).
    9. Borjesson, Pal & Gustavsson, Leif, 2000. "Greenhouse gas balances in building construction: wood versus concrete from life-cycle and forest land-use perspectives," Energy Policy, Elsevier, vol. 28(9), pages 575-588, July.
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