Mapping construction sector greenhouse gas emissions: a crucial step in sustainably meeting increasing housing demands

Hatzav Yoffe, Keagan Rankin, Chris Bachmann, I. D. Posen, Shoshanna Saxe
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引用次数: 1

Abstract

This paper examines the tension between needing to build more infrastructure and housing and simultaneously reduce greenhouse gas emissions (GHG) to avoid the most catastrophic impacts of climate change. This study uses an Environmentally Extended Input-Output (EEIO) approach to conduct a high-resolution top-down analysis of Canada's national construction GHG emissions. Our findings highlight that Canada's current construction practices cannot accommodate the construction required to restore housing affordability by 2030 without substantial environmental consequences. On a consumption life cycle basis, the construction sector was responsible for approximately 90 Mt CO2e in 2018, equivalent to over 8% of Canada’s total GHG emissions, while delivering less than a third of Canada’s annual housing needs. Residential construction was responsible for the largest share (42%) of total construction emissions. Overall, 84% of emissions are from material manufacturing and 35% of construction emissions are imported, underscoring the need for a comprehensive regulatory framework addressing both domestic and imported emissions. Under current construction practices (i.e., current material use patterns and emissions intensities), meeting Canada’s 2030 housing affordability and climate commitments requires an 83% reduction in GHG emissions per construction product (i.e., per home) compared to the 40% economy-wide reduction promised in Canada’s international reduction commitments. Mitigating the GHG gap between emission caps and housing demand calls for changes in the ratio of housing to other infrastructure (e.g. fewer roads, less fossil fuel infrastructure), new construction approaches (e.g. increasing material efficiency) and/or disproportionally allocating climate budget to construction. The implications of our study extend beyond Canada, offering valuable insights for other growing countries with climate goals. The results emphasize the urgency in considering and establishing sectoral GHG budgets for construction and for transformative changes in the construction sector to meet national GHG emission reduction commitments.
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绘制建筑业温室气体排放图:可持续满足日益增长的住房需求的关键一步
本文探讨了需要建设更多基础设施和住房与同时减少温室气体排放(GHG)以避免气候变化带来的最大灾难性影响之间的矛盾。本研究采用环境扩展投入产出(EEIO)方法,对加拿大全国建筑业温室气体排放量进行了高分辨率的自上而下分析。我们的研究结果表明,加拿大目前的建筑实践无法在不对环境造成严重影响的情况下,满足到 2030 年恢复住房可负担性的建筑需求。在消费生命周期的基础上,2018 年建筑行业的二氧化碳排放量约为 9000 万吨 CO2e,相当于加拿大温室气体排放总量的 8%以上,而每年的住房需求量却不到加拿大的三分之一。住宅建筑占建筑业总排放量的最大份额(42%)。总体而言,84% 的排放来自材料制造,35% 的建筑排放来自进口,这突出表明需要一个全面的监管框架来解决国内和进口排放问题。根据目前的建筑实践(即目前的材料使用模式和排放强度),要实现加拿大 2030 年的住房可负担性和气候承诺,每个建筑产品(即每户)的温室气体排放量需要减少 83%,而加拿大在国际减排承诺中承诺的整个经济减排量为 40%。要缩小排放上限与住房需求之间的温室气体差距,需要改变住房与其他基础设施的比例(如减少道路、减少化石燃料基础设施)、采用新的建筑方法(如提高材料效率)和/或将气候预算不成比例地分配给建筑业。我们研究的意义超出了加拿大的范围,为其他有气候目标的成长中国家提供了宝贵的见解。研究结果强调了考虑和制定建筑部门温室气体预算以及建筑部门转型变革以实现国家温室气体减排承诺的紧迫性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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