Your search keyword '"Chen, De"' showing total 2 results

1. Towards low-carbon consumption and cleaner methanol production via hybrid hydrogen supply strategy: A techno-economic-environment assessment.

Author

Zhou, Xin, Sun, Zongzhuang, Liu, Jixiang, Yan, Hao, Feng, Xiang, Chen, De, and Yang, Chaohe

Subjects

*METHANOL production, *GREEN business, *METHANOL as fuel, *WATER electrolysis, *HYDROGEN as fuel, *COALBED methane, *HYDROGEN

Abstract

• A assessment framework of methanol production integrated with a hybrid hydrogen strategy is established. • To comprehensively utilize hydrogen, "balance points" are proposed and defined. • The detailed techno-economic-environment performance are calculated. • The novel hybrid hydrogen supply strategy shows superior performance. A techno-economic-environment assessment framework of methanol production from coal integrated with a hybrid hydrogen supply strategy is established, gathering an insightful perspective of its broad sustainability and providing an effectually hybrid green, blue, and gray hydrogen supply plan to evaluate its performance. Process simulation and life-cycle analysis indicate that coal to methanol integrated with reverse water gas shift using coal to hydrogen (CTM-RWGS-CTH) and CTM-RWGS with water electrolysis using wind energy process show relatively independent excellent technical and environmental performance, respectively. To comprehensively utilize hydrogen energy to realize process integration and intensification, "balance points" are proposed and defined. Moreover, eleven possible hybrid hydrogen supply modes are developed and analyzed. Results show that the quaternary H 2 supply strategy exhibits enormous economic advantages, 0.051 $/kg methanol. The "balance point" in the quaternary H 2 supply strategy is CTM-RWGS-CTH 13%, CTM-RWGS H 2 from CTH without carbon capture, utilization and storage 37%, CTM-RWGS H 2 from byproduct gas to hydrogen 16%, and CTM-RWGS H 2 from water electrolysis using wind energy process 34%. Our hybrid hydrogen supply strategy embraces the full potential role of emerging CTM-RWGS processes to achieve low-carbon consumption and cleaner production, which should prevail over purely unitary hydrogen resources. [ABSTRACT FROM AUTHOR]

Published

2024

2. Engineering Ru atomic structures toward enhanced kinetics of hydrogen generation.

Author

Fu, Wenzhao, Wang, Qianhong, Chen, Wenyao, Qian, Gang, Zhang, Jing, Chen, De, Yuan, Weikang, Zhou, Xinggui, and Duan, Xuezhi

Subjects

*ATOMIC structure, *INTERSTITIAL hydrogen generation, *HYDROGEN as fuel, *STERIC hindrance, *BINDING energy, *ENGINEERING, *RUTHENIUM catalysts, *BIMETALLIC catalysts

Abstract

• Engineering of Ru atomic structure by fine-tuning Cl and Co coordination. • Acid-leaching of bimetallic catalyst for a 4.1-fold increase of H 2 generation rate. • Cl geometric effects of site blockage and steric hindrance as the main factors. • Kinetics switch from a Cl coverage-limited to a reactant activation regime. Herein, we demonstrate a strategy of engineering Ru atomic structures by fine-tuning Cl and Co coordination to synergize the quantity and quality of Ru active sites for boosting hydrogen generation from ammonia borane hydrolysis, via engineering the Cl-free/Cl-containing monometallic Ru catalysts and Co-leaching/Co-containing bimetallic Ru-Co catalysts. Under similar Ru particle sizes, the correlation between Ru binding energy and hydrogen generation activity affords a quantitative discrimination of Ru electronic and geometric contributions, where the site blockage and steric hindrance of Ru by Cl are more detrimental to hydrogen generation compared with the electronic modification by charge donation from Co to Ru. Reversely, the acid-leaching of Co from bimetallic catalysts creates abundant edge-like Ru active sites with much lower H 2 O activation barrier, as indicated by the kinetics switch from a Cl coverage-limited regime to a reactant activation regime, thus yielding a significant 4.1-fold increase in hydrogen generation activity. [ABSTRACT FROM AUTHOR]

Published

2021