冯于川
职称:副教授
学历:博士研究生
学科:动力工程及工程热物理
研究领域或方向:1.CO2捕集及利用技术 2.火电机组调峰技术
邮箱:fengyuchuan@tyut.edu.cn
- 主讲课程
- 学术兼职
- 学术论文
- 主持项目
新能源技术
环境保护与可持续发展
环境保护与可持续发展
Chemical Engineering Journal等期刊审稿人
(1) Revealing the mechanism of hydration on the CO2 kinetic adsorption ofCaO surface via ReaxFF MD simulations with experiments. Applied Surface Science. 2024, 670: 160652. (通讯作者,SCI二区TOP)
(2) Calcium-based pellets for continuous hydrogen production by sorption-enhanced steam methane reforming. International Journal of Hydrogen Energy. 2024, 49: 897-909. (通讯作者,SCI二区)
(3) Sintering Mechanism of Fe2O3 Particles during Iron-Based ChemicalLooping Combustion by Using ReaxFF MD Simulation andExperiments.Energy & Fuels. 2024, 38: 8928-8937. (第一作者,SCI三区)
(4) Understanding the synergistic effect of Ni/Al2O3 on CO2 adsorption andsintering properties of CaO in sorption-enhanced steam reforming process. Fuel, 2023, 341: 127766. (通讯作者,SCI一区TOP)
(5) Exploration of the reaction mechanism of theLaFeO3 oxygen carrier for chemical-loopingsteam methane reforming: a DFT study. Physical Chemistry Chemical Physics, 2023, 25: 13033–13040. (第一作者,SCI三区)
(6)Reaction mechanism of methane conversion over Ca2Fe2O5 oxygen carrier in chemical looping hydrogen production. Fuel, 2021, 290: 120094. (第一作者,SCI一区TOP)
(7) Dopant screening of modified Fe2O3 oxygen carriers in chemical looping hydrogen production. Fuel, 2020, 262: 116489. (第一作者,SCI一区TOP)
(8)Characteristics of dopant distribution and surface oxygen vacancy formation for modified Fe2O3 in chemical looping combustion. Fuel, 2020, 276: 117942. (第一作者,SCI一区TOP)
(9)Reaction mechanism of Ca2Fe2O5 oxygen carrier with CO in chemical looping hydrogen production. Applied Surface Science, 2020, 534: 147583. (第一作者,SCI二区TOP)
(10)Density functional theory study on improved reactivity of alkali-doped Fe2O3 oxygen carriers for chemical looping hydrogen production. Fuel, 2019, 236: 1057-1064. (第一作者,SCI一区TOP)
(11)Influence mechanism of supports on the reactivity of Ni-based oxygen carriers for chemical looping reforming: A DFT study. Fuel, 2018, 229: 88-94. (第一作者,SCI一区TOP)
(12) Study of reaction mechanism of methane conversion over Ni-based oxygen carrier in chemical looping reforming. Fuel, 2017, 210: 866-872. (第一作者,SCI一区TOP)
(13) Influence mechanism of H2S on the reactivity of Ni-based oxygen carriers for chemical-looping combustion. Chemical Engineering Journal, 2016, 295: 461-467. (第一作者,SCI一区TOP)
(14) 化学链重整过程中LaFeO3载氧体的CH4部分氧化反应机理研究. 燃料化学学报(中英文), 2024, 52(04): 586-594. (通讯作者,EI)
(2) Calcium-based pellets for continuous hydrogen production by sorption-enhanced steam methane reforming. International Journal of Hydrogen Energy. 2024, 49: 897-909. (通讯作者,SCI二区)
(3) Sintering Mechanism of Fe2O3 Particles during Iron-Based ChemicalLooping Combustion by Using ReaxFF MD Simulation andExperiments.Energy & Fuels. 2024, 38: 8928-8937. (第一作者,SCI三区)
(4) Understanding the synergistic effect of Ni/Al2O3 on CO2 adsorption andsintering properties of CaO in sorption-enhanced steam reforming process. Fuel, 2023, 341: 127766. (通讯作者,SCI一区TOP)
(5) Exploration of the reaction mechanism of theLaFeO3 oxygen carrier for chemical-loopingsteam methane reforming: a DFT study. Physical Chemistry Chemical Physics, 2023, 25: 13033–13040. (第一作者,SCI三区)
(6)Reaction mechanism of methane conversion over Ca2Fe2O5 oxygen carrier in chemical looping hydrogen production. Fuel, 2021, 290: 120094. (第一作者,SCI一区TOP)
(7) Dopant screening of modified Fe2O3 oxygen carriers in chemical looping hydrogen production. Fuel, 2020, 262: 116489. (第一作者,SCI一区TOP)
(8)Characteristics of dopant distribution and surface oxygen vacancy formation for modified Fe2O3 in chemical looping combustion. Fuel, 2020, 276: 117942. (第一作者,SCI一区TOP)
(9)Reaction mechanism of Ca2Fe2O5 oxygen carrier with CO in chemical looping hydrogen production. Applied Surface Science, 2020, 534: 147583. (第一作者,SCI二区TOP)
(10)Density functional theory study on improved reactivity of alkali-doped Fe2O3 oxygen carriers for chemical looping hydrogen production. Fuel, 2019, 236: 1057-1064. (第一作者,SCI一区TOP)
(11)Influence mechanism of supports on the reactivity of Ni-based oxygen carriers for chemical looping reforming: A DFT study. Fuel, 2018, 229: 88-94. (第一作者,SCI一区TOP)
(12) Study of reaction mechanism of methane conversion over Ni-based oxygen carrier in chemical looping reforming. Fuel, 2017, 210: 866-872. (第一作者,SCI一区TOP)
(13) Influence mechanism of H2S on the reactivity of Ni-based oxygen carriers for chemical-looping combustion. Chemical Engineering Journal, 2016, 295: 461-467. (第一作者,SCI一区TOP)
(14) 化学链重整过程中LaFeO3载氧体的CH4部分氧化反应机理研究. 燃料化学学报(中英文), 2024, 52(04): 586-594. (通讯作者,EI)
(1) 山西省基础研究计划青年项目:化学链燃烧中粉煤灰基载氧体颗粒的制备工艺研究(2022.01-2024.12),主持,在研。
(2) 企业委托项目:粉煤灰基载氧体技术开发(2024.07-2025.12),主持,在研。
(3) 企业委托项目:循环流化床粉煤灰复合颗粒制备技术研究(2023.08-2025.08),主持,在研。
(4) 山西省重大专项:循环流化床复合燃烧快速调峰关键技术及工程示范(2022.11-2025.11),参与,在研。
(5) 国家重点研发计划项目:低热值煤清洁高效燃烧资源利用与灵活发电关键技术(2020.12-2023.11),参与,结题。
(6)国家重点实验室开放课题:基于Fe2O3/粉煤灰载氧体的化学链燃烧特性研究(2022.01-2023.12),主持,结题。
(7)中国博士后科学基金面上项目:基于改性铁基载氧体的化学链制氢研究(2019.11-2021.6),主持,结题。
(2) 企业委托项目:粉煤灰基载氧体技术开发(2024.07-2025.12),主持,在研。
(3) 企业委托项目:循环流化床粉煤灰复合颗粒制备技术研究(2023.08-2025.08),主持,在研。
(4) 山西省重大专项:循环流化床复合燃烧快速调峰关键技术及工程示范(2022.11-2025.11),参与,在研。
(5) 国家重点研发计划项目:低热值煤清洁高效燃烧资源利用与灵活发电关键技术(2020.12-2023.11),参与,结题。
(6)国家重点实验室开放课题:基于Fe2O3/粉煤灰载氧体的化学链燃烧特性研究(2022.01-2023.12),主持,结题。
(7)中国博士后科学基金面上项目:基于改性铁基载氧体的化学链制氢研究(2019.11-2021.6),主持,结题。
