| Co-hydrothermal carbonization of organic solid wastes to hydrochar as potential fuel: a review Q Wang, S Wu, D Cui, H Zhou, D Wu, S Pan, F Xu, Z Wang Science of the Total Environment 850, 158034, 2022 | 146 | 2022 |
| Three-dimensional structure of a huadian oil shale kerogen model: An experimental and theoretical study XH Guan, Y Liu, D Wang, Q Wang, MS Chi, S Liu, CG Liu Energy & Fuels 29 (7), 4122-4136, 2015 | 113 | 2015 |
| Thermal evolution of chemical structure and mechanism of oil sands bitumen Z Wang, Q Wang, C Jia, J Bai Energy 244, 123190, 2022 | 111 | 2022 |
| Interactions and kinetic analysis of oil shale semi-coke with cornstalk during co-combustion Q Wang, W Zhao, H Liu, C Jia, S Li Applied energy 88 (6), 2080-2087, 2011 | 97 | 2011 |
| Initial pyrolysis mechanism and product formation of cellulose: An Experimental and Density functional theory (DFT) study Q Wang, H Song, S Pan, N Dong, X Wang, S Sun Scientific Reports 10 (1), 3626, 2020 | 95 | 2020 |
| Hydrothermal carbonization of food waste for sustainable biofuel production: Advancements, challenges, and future prospects S Wu, Q Wang, M Fang, D Wu, D Cui, S Pan, J Bai, F Xu, Z Wang Science of The Total Environment 897, 165327, 2023 | 92 | 2023 |
| Strategy of Huadian oil shale comprehensive utilization W Qing, B Jingru, S Baizhong, S Jian Oil Shale 22 (3), 305, 2005 | 91 | 2005 |
| Chemical Composition and Structural Characteristics of Oil Shales and Their Kerogens Using Fourier Transform Infrared (FTIR) Spectroscopy and Solid-State 13C … Q Wang, J Ye, H Yang, Q Liu Energy & Fuels 30 (8), 6271-6280, 2016 | 86 | 2016 |
| Interactions between oil shale and its semi-coke during co-combustion Q Wang, H Wang, B Sun, J Bai, X Guan Fuel 88 (8), 1520-1529, 2009 | 86 | 2009 |
| ReaxFF-based molecular dynamics simulation of the initial pyrolysis mechanism of lignite F Xu, H Liu, Q Wang, S Pan, D Zhao, Q Liu, Y Liu Fuel Processing Technology 195, 106147, 2019 | 84 | 2019 |
| PYROLYSIS CHARACTERISTICS OF HUADIAN OIL SHALES. W Qing, S Baizhong, H Aijuan, B Jingru, L Shaohua Oil Shale 24 (2), 2007 | 82 | 2007 |
| Kinetic study of Huadian oil shale combustion using a multi-stage parallel reaction model Y Sun, F Bai, X Lü, C Jia, Q Wang, M Guo, Q Li, W Guo Energy 82, 705-713, 2015 | 80 | 2015 |
| Influence of air oxidative and non-oxidative torrefaction on the chemical properties of corn stalk Q Wang, S Sun, X Zhang, H Liu, B Sun, S Guo Bioresource Technology 332, 125120, 2021 | 74 | 2021 |
| Pyrolysis temperature effect on compositions of basic nitrogen species in Huadian shale oil using positive-ion ESI FT-ICR MS and GC-NCD D Cui, J Li, X Zhang, L Zhang, H Chang, Q Wang Journal of Analytical and Applied Pyrolysis 153, 104980, 2021 | 73 | 2021 |
| Investigation of heat transfer mechanisms among particles in horizontal rotary retorts Q Wang, B Liu, Z Wang Powder Technology 367, 82-96, 2020 | 70 | 2020 |
| Evaluation of fuel properties and combustion behaviour of hydrochar derived from hydrothermal carbonisation of agricultural wastes S Wu, Q Wang, D Cui, H Sun, H Yin, F Xu, Z Wang Journal of the Energy Institute 108, 101209, 2023 | 68 | 2023 |
| Experimental and dynamics simulation studies of the molecular modeling and reactivity of the Yaojie oil shale kerogen Q Wang, S Pan, J Bai, M Chi, D Cui, Z Wang, Q Liu, F Xu Fuel 230, 319-330, 2018 | 68 | 2018 |
| Characterization of organic nitrogen and sulfur in the oil shale kerogens Q Wang, Q Liu, ZC Wang, HP Liu, JR Bai, JB Ye Fuel Processing Technology 160, 170-177, 2017 | 68 | 2017 |
| Effect of CaO on pyrolysis products and reaction mechanisms of a corn stover Q Wang, X Zhang, S Sun, Z Wang, D Cui Acs Omega 5 (18), 10276-10287, 2020 | 67 | 2020 |
| A review of eutectic salts as phase change energy storage materials in the context of concentrated solar power Q Wang, C Wu, X Wang, S Sun, D Cui, S Pan, H Sheng International Journal of Heat and Mass Transfer 205, 123904, 2023 | 65 | 2023 |
