合成气
甲烷化
二氧化碳重整
催化作用
废物管理
烟气
催化重整
材料科学
碳纤维
二氧化碳
垃圾衍生燃料
二甲醚
合成燃料
蒸汽重整
化学工程
环境科学
氧化物
甲烷转化炉
城市固体废物
炭黑
镁
工业废物
生物量(生态学)
燃料气
纳米晶材料
甲烷
作者
Seok‐Jin Kim,Raghu V. Maligal‐Ganesh,Javeed Mahmood,Phil Woong Kang,Aadesh Harale,Abdulrahman S. AlSuhaibani,Qingyuan Hu,Ammar Alahmed,Aqil Jamal,Rukaiyat Suleiman,Husain Baaqel,Mert Atilhan,S. Mani Sarathy,Cafer T. Yavuz
出处
期刊:Science
[American Association for the Advancement of Science]
日期:2026-06-25
卷期号:392 (6805): 1369-1374
标识
DOI:10.1126/science.adp5208
摘要
Strategies for lowering carbon emissions from hydrocarbons and waste must overcome the challenges related to catalyst durability and the presorting of waste. Reforming low-value carbon sources with carbon dioxide (CO 2 ) offers an industrial-scale pathway for recycling waste streams into fuels and chemicals. We developed a nickel-molybdenum alloy nanocatalyst on single-crystalline magnesium oxide (NiMoCat) in pellet form on a kilogram scale suitable for high-pressure industrial reactors. Aliphatic hydrocarbons (methane, n -butane) and aromatics (benzene, toluene) under pressurized CO 2 yielded quantitative syngas without methanation or undesired oxidative by-products, such as butadiene or polyaromatics. Scaled-up NiMoCat maintains activity during long-term operation and enables a two-step process involving gasification of unsorted waste followed by hybrid reforming under realistic flue gas or CO 2 flow. A detailed life-cycle analysis of biogas-to-dimethyl ether conversion showcases a scalable, sustainable CO 2 utilization compatible with current fuel and chemical infrastructures.
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