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迈向采用细菌代谢的低二氧化碳排放建筑材料(2/2):减少混凝土行业全球变暖潜能的前景。

Towards a low CO2 emission building material employing bacterial metabolism (2/2): Prospects for global warming potential reduction in the concrete industry.

机构信息

Pure Logic AS, Oslo, Norway.

RISE Research Institutes of Sweden, Göteborg, Sweden.

出版信息

PLoS One. 2019 Apr 16;14(4):e0208643. doi: 10.1371/journal.pone.0208643. eCollection 2019.

DOI:10.1371/journal.pone.0208643
PMID:30990800
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6467374/
Abstract

The production of concrete is one of the most significant contributors to global greenhouse gas emissions. This work focuses on bio-cementation-based products and their potential to reduce global warming potential (GWP). In particular, we address a proposed bio-cementation method employing bacterial metabolism in a two-step process of limestone dissolution and recrystallisation (BioZEment). A scenario-based techno-economic analysis (TEA) is combined with a life cycle assessment (LCA), a market model and a literature review of consumers' willingness to pay, to compute the expected reduction of global GWP. Based on the LCA, the GWP of 1 ton of BioZEment is found to be 70-83% lower than conventional concrete. In the TEA, three scenarios are investigated: brick, precast and onsite production. The results indicate that brick production may be the easiest way to implement the products, but that due to high cost, the impact on global GWP will be marginal. For precast production the expected 10% higher material cost of BioZEment only produces a marginal increase in total cost. Thus, precast production has the potential to reduce global GWP from concrete production by 0-20%. Significant technological hurdles remain before BioZEment-based products can be used in onsite construction scenarios, but in this scenario, the potential GWP reduction ranges from 1 to 26%. While the potential to reduce global GWP is substantial, significant efforts need to be made both in regard to public acceptance and production methods for this potential to be unlocked.

摘要

混凝土的生产是全球温室气体排放的主要贡献者之一。这项工作专注于基于生物胶结的产品及其减少全球变暖潜势(GWP)的潜力。特别是,我们研究了一种拟议的生物胶结方法,该方法利用细菌代谢在两步过程中溶解和再结晶石灰石(BioZEment)。基于情景的技术经济分析(TEA)与生命周期评估(LCA)、市场模型和消费者支付意愿的文献综述相结合,以计算全球 GWP 的预期减少量。基于 LCA,发现 1 吨 BioZEment 的 GWP 比传统混凝土低 70-83%。在 TEA 中,研究了三个情景:砖、预制和现场生产。结果表明,砖生产可能是实施这些产品最简单的方法,但由于成本高,对全球 GWP 的影响将是微不足道的。对于预制生产,BioZEment 的预期 10%更高的材料成本只会使总成本略有增加。因此,预制生产有可能将混凝土生产的全球 GWP 减少 0-20%。在生物胶结产品可用于现场施工情景之前,仍存在重大技术障碍,但在这种情况下,潜在的 GWP 减少范围从 1%到 26%。虽然减少全球 GWP 的潜力很大,但需要在公众接受度和生产方法方面做出重大努力,才能释放这种潜力。

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