加州大学戴维斯分校和斯坦福大学的研究人员发现，用可固碳的替代材料替换传统建材，每年可封存高达160亿吨二氧化碳，相当于人类年排放量的一半。研究考察了碳酸盐基骨料、生物质纤维等材料在砖中的固碳潜力。尽管努力减少碳排放，但人类仍可能在2050年后产生大量二氧化碳，因此碳封存是重要补充手段。研究提出用改性建材固碳，如用碳酸盐骨料替代混凝土和沥青中的传统骨料，并增加木材、生物质纤维砖和生物炭的使用。结果表明，即使仅替换部分材料，也能封存大量二氧化碳，为实现气候目标提供新思路。

🧱 研究发现，用碳酸盐基骨料替换混凝土中的传统骨料，并结合生物炭、木材、生物质纤维砖等材料，每年可封存高达160亿吨二氧化碳，这相当于人类年排放量的一半。

🌱 研究人员通过假设所有混凝土骨料都被碳酸盐基材料替代，并补充15%的生物炭和碳酸盐水泥，增加20%的木材用量，以及用生物质补充15%的砖块，计算出160亿吨的固碳潜力。此外，用生物基塑料和生物油替代建筑中使用的塑料和沥青。

♻️ 即使不立即采用这些技术，在2075年至2100年间应用，仍然可以达到《政府间气候变化专门委员会（IPCC）》设定的目标，前提是所有其他脱碳努力也得到实施。研究强调，除减少碳排放外，还需要清除大气中已有的二氧化碳，而建筑材料因其产量巨大和耐久性，是碳储存的良好选择。

💰 研究指出，目前已存在可用的资源，如富含矿物质的废物流，可用于替换10%的传统骨料，仅此一项就可储存10亿吨二氧化碳。然而，传统建材如混凝土和塑料成本低廉，需要政策和经济激励措施，鼓励行业转向低碳材料。

Replacing conventional building materials with alternatives that sequester carbon dioxide could allow the world to lock away up to half the CO₂ generated by humans each year – about 16 billion tonnes. This is the finding of researchers at the University of California Davis and Stanford University, both in the US, who studied the sequestration potential of materials such as carbonate-based aggregates and biomass fibre in brick.

Despite efforts to reduce greenhouse gas emissions by decarbonizing industry and switching to renewable sources of energy, it is likely that humans will continue to produce significant amounts of CO₂ beyond the target “net zero” date of 2050. Carbon storage and sequestration – either at source or directly from the atmosphere – are therefore worth exploring as an additional route towards this goal. Researchers have proposed several possible ways of doing this, including injecting carbon underground or deep under the ocean. However, all these scenarios are challenging to implement practically and pose their own environmental risks.

Modifying common building materials

In the present work, a team of civil engineers and earth systems scientists led by Elisabeth van Roijen (then a PhD student at UC Davis) calculated how much carbon could be stored in modified versions of several common building materials. These include concrete (cement) and asphalt containing carbonate-based aggregates; bio-based plastics; wood; biomass-fibre bricks (from waste biomass); and biochar filler in cement.

The researchers obtained the “16 billion tonnes of CO₂” figure by assuming that all aggregates currently employed in concrete would be replaced with carbonate-based versions. They also supplemented 15% of cement with biochar and the remainder with carbonatable cements; increased the amount of wood used in all new construction by 20%; and supplemented 15% of bricks with biomass and the remainder with carbonatable calcium hydroxide. A final element in their calculation was to replace all plastics used in construction today with bio-based plastics and all bitumen with bio-oil in asphalt.

“We calculated the carbon storage potential of each material based on the mass ratio of carbon in each material,” explains van Roijen. “These values were then scaled up based on 2016 consumption values for each material.”

“The sheer magnitude of carbon storage is pretty impressive”

While the production of some replacement materials would need to increase to meet the resulting demand, van Roijen and colleagues found that resources readily available today – for example, mineral-rich waste streams – would already let us replace 10% of conventional aggregates with carbonate-based ones. “These alone could store 1 billion tonnes of CO₂,” she says. “The sheer magnitude of carbon storage is pretty impressive, especially when you put it in context of the level of carbon dioxide removal needed to stay below the 1.5 and 2 °C targets set by The Intergovernmental Panel on Climate Change (IPCC).”

Indeed, even if the world doesn’t implement these technologies until 2075, we could still store enough carbon between 2075 and 2100 to stay below these targets, she tells Physics World. “This is assuming, of course, that all other decarbonization efforts outlined in the IPCC reports are also implemented to achieve net-zero emissions,” she says.

Building materials are a good option for carbon storage

The motivation for the study, she explains, came from the urgent need – as expressed by the IPCC – to not only reduce new carbon emissions through rapid and significant decarbonization, but to also remove large amounts of CO₂ already present in the atmosphere. “Rather than burying it in geological, terrestrial or ocean reservoirs, we wanted to look into the possibility of leveraging existing technology – namely conventional building materials – as a way to store CO₂. Building materials are a good option for carbon storage given the massive quantity (30 billion tonnes) produced each year, not to mention their durability.”

Van Roijen, who is now a postdoctoral researcher at the US Department of Energy Renewable Energy Laboratory, hopes that this work, which is detailed in Science, will go beyond the reach of the research lab and attract the attention of policymakers and industrialists. While some of the technologies outlined in this study are new and require further research, others, such as bio-based plastics, are well established and simply need some economic and political support, she says. “That said, conventional building materials such as concrete and plastics are pretty cheap, so there will need to be some incentive for industries to make the switch over to these low-carbon materials.”

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