Reports from the Frontier: Electrifying Chemical Transformations and Separations to Valorize Wastewater Nitrogen

IF 1.7 Q4 ELECTROCHEMISTRY
Matthew J. Liu, W. Tarpeh
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引用次数: 0

Abstract

Ammonia is an essential compound to modern society, underpinning fertilizer production and chemical manufacturing. Global ammonia demand currently exceeds 150 million tons a year and is projected to increase over 2% annually. Over 96% of ammonia is currently generated through the Haber-Bosch (HB) process, in which steam-reformed hydrogen reacts with nitrogen under reaction conditions that consume 1–2% of global energy and contribute 1.2–1.4% of anthropogenic CO2 emissions every year. In an environmental context, ammonia is a form of reactive nitrogen. Large amounts of reactive nitrogen, such as HB ammonia, accumulate in the biosphere because 80% of wastewater globally is discharged without treatment. The resulting skew in the global nitrogen cycle leads to imbalanced ecosystems and threatens water quality. Conventional water treatment removes reactive nitrogen by converting it to N2 (biological nitrification–denitrification); at HB facilities, the N2 is then cycled back to produce ammonia. Directly valorizing reactive nitrogen in waste streams would shortcut the use of N2 as an intermediate in water remediation and ammonia production, allowing savings in energy, emissions, and costs. Indeed, treating nitrogen as a resource to recover rather than simply a pollutant to remove aligns with the US National Academy of Engineering’s call to manage the nitrogen cycle, a challenge central to chemical manufacturing and ecosystem protection.
前沿报道:电解化学转化和分离法对废水氮进行Valorize
氨是现代社会的一种重要化合物,是化肥生产和化学制造的基础。目前,全球氨需求每年超过1.5亿吨,预计每年增长2%以上。目前,超过96%的氨是通过Haber Bosch(HB)工艺产生的,在该工艺中,蒸汽重整的氢气与氮气在反应条件下反应,每年消耗全球能源的1-2%,贡献人类二氧化碳排放的1.2-1.4%。在环境背景下,氨是活性氮的一种形式。大量的活性氮,如HB氨,在生物圈中积累,因为全球80%的废水都是未经处理排放的。由此造成的全球氮循环扭曲导致生态系统失衡,并威胁到水质。常规水处理通过将活性氮转化为N2(生物硝化-反硝化)来去除活性氮;在HB设施中,N2然后循环返回以产生氨。直接对废物流中的活性氮进行定价将缩短N2作为水修复和氨生产中间体的使用,从而节省能源、排放和成本。事实上,将氮视为一种需要回收的资源,而不仅仅是一种需要去除的污染物,这与美国国家工程院管理氮循环的呼吁一致,氮循环是化学制造和生态系统保护的核心挑战。
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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来源期刊
CiteScore
2.10
自引率
5.60%
发文量
62
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