| 1 |
Further discussion on the mechanism of hydrogen transfer in direct coal liquefaction
Wang XB, Fan HH, Xie ZZ, Li WY
Catalysis Today, 374, 185, 2021 |
| 2 |
Selective catalytic hydrogenation of naphthalene to tetralin over a Ni-Mo/Al2O3 catalyst
Su XP, An P, Gao JW, Wang RC, Zhang YJ, Li X, Zhao YK, Liu YQ, Ma XX, Sun M
Chinese Journal of Chemical Engineering, 28(10), 2566, 2020 |
| 3 |
Direct Coal Liquefaction Using Iron Carbonyl Powder Catalyst
Lokhat D, Carsky M
Chemical Engineering & Technology, 42(4), 818, 2019 |
| 4 |
Designing supported NiMoS2 catalysts for hydrocracking of vacuum residue
Park HB, Lee YK
Fuel, 239, 1265, 2019 |
| 5 |
Molecular footprint of co-solvents in hydrothermal liquefaction (HTL) of Fallopia Japonica
Arturi KR, Kucheryayskiy S, Nielsen RP, Maschietti M, Vogel F, Bjelic S, Sogaard EG
Journal of Supercritical Fluids, 143, 211, 2019 |
| 6 |
Upgrading of petroleum vacuum residue using a hydrogen-donor solvent with acid-treated carbon
Kim DW, Jeon PR, Moon S, Lee CH
Energy Conversion and Management, 161, 234, 2018 |
| 7 |
Promoting asphaltene conversion by tetralin for hydrocracking of petroleum pitch
Park HB, Kim KD, Lee YK
Fuel, 222, 105, 2018 |
| 8 |
Effects of the variation in diesel fuel components on the particulate matter and unregulated gaseous emissions from a common rail diesel engine
Li ZL, Liu GB, Cui XF, Sun XY, Li S, Qian Y, Jiang CX, Lu XC
Fuel, 232, 279, 2018 |
| 9 |
Study on the thermal liquefaction of Xilinguole lignite in solvent at high temperature
Wang ZC, Li L, Hu RN, Wang XL, Pan CX, Kang SG, Ren SB, Lei ZP, Shui HF
Fuel Processing Technology, 176, 167, 2018 |
| 10 |
Design of selective hydrocracking catalysts for BTX production from diesel-boiling-range polycyclic aromatic hydrocarbons
Shin J, Oh Y, Choi Y, Lee J, Lee JK
Applied Catalysis A: General, 547, 12, 2017 |
