赵希强
个人信息Personal Information
副教授 硕士生导师
性别:男
在职信息:在职
所在单位:能源与动力工程学院
入职时间:2010-07-23
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- [21] 曹涵. ZIF-8 based dual scale superhydrophobic membrane for membrane distillation. Desalination, 2023.
- [22] 高一博. Microwave-triggered low temperature thermal reduction of Zr-modified high entropy oxides with extraordinary thermochemical H2 production performance. ENERGY CONVERSION AND MANAGEMENT, 252, 2022.
- [23] 王超前. A stepwise microwave synergistic pyrolysis approach to produce sludge-based biochars: Optimizing and mechanism of heavy metals immobilization. Fuel, 2022.
- [24] . Alkaline etched hydrochar–based magnetic adsorbents produced from pharmaceutical industry waste for organic dye removal. Environmental Science and Pollution Research, 2023.
- [25] 孙静. Discovering the key role of MnO2 and CeO2 particles in the Fe2O3 catalysts for enhancing the catalytic oxidation of VOC: Synergistic effect of the lattice oxygen species and surface-adsorbed oxygen. Science of the total Environment, 2022.
- [26] 贾平山. Construction of N-doped porous carbon-coated Fe3O4 with efficient ion transfer performance for enhanced-performance Lithium storage. Electrochimica Acta, 428, 2022.
- [27] 董一霖. Study on the synergy effect of MnOx and support on catalytic ozonation of toluene. Chemosphere, 303, 2022.
- [28] 赵希强. Desulfurization characteristics and mechanism of iron oxide-modified bio-carbon materials. Energy , 2022.
- [29] 赵希强. 生物质炭改性微球去除化工废水中无机磷的性能研究. 化工学报(中、英文版), 73, 2022.
- [30] 赵希强. Biochar-embedding iron-alginate microspheres derived from bagasse by one-step microwave pyrolysis/activation for enhanced Cr(VI) removal. Frontiers in Energy Research, 2022.
- [31] 赵希强. Evaluating the effect of torrefaction on the pyrolysis of biomass and the biochar catalytic performance on dry reforming of methane. Renewable Energy , 313, 2022.
- [32] 张健. Effects of Cobalt-Doped Modification on the Catalytic Reduction of SO2 with CO over an Iron/BFS Catalyst. Energy and Fuels, 35, 20250, 2021.
- [33] 赵希强. Microwave steam gasification of semi-coke derived from co-pyrolysis of fungus chaff and lignite. INTERNATIONAL JOURNAL OF COAL PREPARATION AND UTILIZATION, 41, 830, 2021.
- [34] 江镇宇. A sustainable strategy for spent Li-ion battery regeneration: microwave-hydrothermal relithiation complemented with anode-revived graphene to construct a LiFePO4/MWrGO cathode material. SUSTAINABLE ENERGY & FUELS, 6, 2207, 2022.
- [35] 宋占龙. Effect of additives on the distribution of three-phase products of oily sludge subjected to microwave pyrolysis. Journal of Environmental Science and Health - Part A Toxic/Hazardous Substances and Environmental Engineering, 56, 1445, 2021.
- [36] 宋占龙. Study on the microwave extraction process and product distribution of essential oils from citrus peel. Chemical Engineering and Processing: Process Intensification, 171, 2022.
- [37] 高一博. Microwave-triggered low temperature thermal reduction of Zr-modified high entropy oxides with extraordinary thermochemical H-2 production performance. Energy Conversion and Management, 252, 2022.
- [38] 曹涵. Thermal-exergy efficiency trade-off optimization of pressure retarded membrane distillation based on TOPSIS model. COMPUTATIONAL SCIENCE AND ITS APPLICATIONS - ICCSA 2005, PT 2, 523, 2022.
- [39] 张富森. Fe/HZSM-5 synergizes with biomass pyrolysis carbon to reform CH4-CO2 to syngas in microwave field. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY Journal, 47, 11153, 2022.
- [40] 孙静. Microwave-induced high-energy sites and targeted energy transition promising for efficient energy deployment. FRONTIERS IN ENERGY, 2021.