- Yang, Hanmin;
- Nuran Zaini, Ilman;
- Pan, Ruming;
- Jin, Yanghao;
- Wang, Yazhe;
- Li, Lengwan;
- Caballero, José;
- Shi, Ziyi;
- Subasi, Yaprak;
- Nurdiawati, Anissa;
- Wang, Shule;
- Shen, Yazhou;
- Wang, Tianxiang;
- Wang, Yue;
- Sandström, Linda;
- Jönsson, Pär;
- Yang, Weihong;
- Han, Tong
This study introduces a distributed electrified heating approach that is able to innovate chemical engineering involving endothermic reactions. It enables rapid and uniform heating of gaseous reactants, facilitating efficient conversion and high product selectivity at specific equilibrium. Demonstrated in catalyst-free CH4 pyrolysis, this approach achieves stable production of H2 (530 g h-1 L reactor -1) and carbon nanotube/fibers through 100% conversion of high-throughput CH4 at 1150 °C, surpassing the results obtained from many complex metal catalysts and high-temperature technologies. Additionally, in catalytic CH4 dry reforming, the distributed electrified heating using metallic monolith with unmodified Ni/MgO catalyst washcoat showcased excellent CH4 and CO2 conversion rates, and syngas production capacity. This innovative heating approach eliminates the need for elongated reactor tubes and external furnaces, promising an energy-concentrated and ultra-compact reactor design significantly smaller than traditional industrial systems, marking a significant advance towards more sustainable and efficient chemical engineering society.