Co-production of steel and chemicals to mitigate hard-to-abate carbon emissions

Yang Guo, Jieyi Lu, Qi Zhang, Yunling Cao, Lyujun Chen, Denise L. Mauzerall
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Abstract

Hard-to-abate sectors emitted ~30% of global CO2 emissions in 2018. As the world’s largest producer of chemicals and steel, China’s mitigation efforts in these sectors are crucial. Here we examine the greenhouse gas mitigation and costs of co-producing steel and chemicals in China by extracting H2 and CO from steelmaking off-gas for chemical production and using a customized optimization model with a life-cycle assessment. Without carbon pricing, co-production reduces greenhouse gas emissions by 36 MtCO2eq yr−1 (−7%) and costs by 1.5 billion CNY per year (−1%) relative to independent production. A carbon price of 350 CNY per tCO2 enhances emissions and cost reductions to 113 MtCO2eq yr−1 (−22%) and 25.5 billion CNY per year (−10%), respectively. Furthermore, 60% of total emissions and cost reductions can be achieved via 24% of connections, ~50% of which are in Hebei, Henan, Shanxi and Shandong provinces. This study demonstrates the cost-effectiveness of using co-production to mitigate these hard-to-abate emissions and the importance of targeting critical connections to obtain the majority of reductions. Achieving a net-zero future requires that hard-to-abate sectors be addressed. Co-production offers an opportunity to mitigate chemical and steel sector emissions by extracting H2 and CO from steelmaking off-gas and using them for chemical syntheses. The authors examine carbon mitigation and costs of co-producing chemicals and steel in China.

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联合生产钢铁和化学品,减少难以消减的碳排放
2018 年,难以减排行业的二氧化碳排放量约占全球排放量的 30%。作为全球最大的化学品和钢铁生产国,中国在这些领域的减排努力至关重要。在此,我们通过从炼钢废气中提取 H2 和 CO 用于化工生产,并使用带有生命周期评估的定制优化模型,研究了中国钢铁和化工联合生产的温室气体减排和成本。在不实行碳定价的情况下,与独立生产相比,联合生产每年可减少 36 兆吨 CO2eq 的温室气体排放(-7%),成本每年减少 15 亿元人民币(-1%)。每吨二氧化碳 350 元人民币的碳价格可将排放量和成本分别提高到每年 1.13 亿吨二氧化碳当量(-22%)和每年 255 亿元人民币(-10%)。此外,通过 24% 的连接可实现总排放量和成本减少量的 60%,其中约 50% 位于河北、河南、山西和山东四省。这项研究表明,利用联合生产来减少这些难以消减的排放具有成本效益,而且针对关键连接来获得大部分减排量也非常重要。实现净零排放的未来需要解决难以减排的行业。通过从炼钢废气中提取 H2 和 CO 并将其用于化学合成,联合生产为减少化工和钢铁行业的排放提供了机会。作者对中国化工和钢铁联合生产的碳减排和成本进行了研究。
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