甲烷化
替代天然气
工艺工程
电力转天然气
天然气
背景(考古学)
发电
计算机科学
能量载体
过程(计算)
甲烷
环境科学
生化工程
可再生能源
合成气
废物管理
化学
催化作用
功率(物理)
工程类
热力学
古生物学
电极
有机化学
电解
电解质
物理化学
物理
电气工程
生物化学
操作系统
生物
出处
期刊:Catalysts
[Multidisciplinary Digital Publishing Institute]
日期:2024-08-26
卷期号:14 (9): 562-562
被引量:2
标识
DOI:10.3390/catal14090562
摘要
Even if huge efforts are made to push alternative mobility concepts, such as electric cars and fuel-cell-powered cars, the significance and use of liquid fuels is anticipated to stay high during the 2030s. Biomethane and synthetic natural gas (SNG) might play a major role in this context, as they are raw material for chemical industry that is easy to be stored and distribute via existing infrastructure, and are a versatile energy carrier for power generation and mobile applications. Since biomethane and synthetic natural gas are suitable for power generation and for mobile applications, they can therefore replace natural gas without any infrastructure changes, thus playing a major role.In this paper, we aim to comprehend the direct production of synthetic natural gas from CO2 and H2 in a Sabatier process based on a thermodynamic analysis as well as a multi-step kinetic approach. For this purpose, we thoroughly discuss CO2 methanation to control emissions in order to maximize the methane formation along with minimizing the CO formation and to understand the complex methanation process. We consider an equilibrium and kinetic modeling study on the NiO-SiO2 catalyst for methanation focusing on CO2-derived SNG. The thermodynamic analysis of CO2 hydrogenation is preformed to define the optimal process parameters followed by the kinetic simulations for catalyst development. The investigation presented in this paper can also be used for developing machine learning algorithms for methanation processes.
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