| 1 |
Combined Process to Recycle Scrap Tire Rubber and Degrade Dye Wastewater with Sub/Supercritical Water
Li X, Yang CH, Yan YT, Deng XQ
Journal of Chemical Engineering of Japan, 53(7), 296, 2020 |
| 2 |
Cryogenic grinding performance of scrap tire rubber by devulcanization treatment with ScCO2
Li X, Xu XF, Liu ZJ
Powder Technology, 374, 609, 2020 |
| 3 |
Transformation of dl Limonene into Aromatic Compounds Using Supported Heteropolyacid Catalysts
Ruiz CPT, Gauthier-Maradei P, Capron M, Pirez C, Gardoll O, Katryniok B, Dumeignil F
Catalysis Letters, 149(1), 328, 2019 |
| 4 |
Insights into pyrolysis and co-pyrolysis of tobacco stalk and scrap tire: Thermochemical behaviors, kinetics, and evolved gas analysis
Chen RJ, Lun LY, Cong KL, Li QH, Zhang YG
Energy, 183, 25, 2019 |
| 5 |
Characterization and upgradation of crude tire pyrolysis oil (CTPO) obtained from a rotating autoclave reactor
Mohan A, Dutta S, Madav V
Fuel, 250, 339, 2019 |
| 6 |
Hydrotreating a waste engine oil and scrap tire oil blend for production of liquid fuel
Liu XJ, Wang F, Zhai LL, Xu YP, Xie LF, Duan PG
Fuel, 249, 418, 2019 |
| 7 |
Clean pyrolysis oil from a continuous two-stage pyrolysis of scrap tires using in-situ and ex-situ desulfurization
Choi GG, Oh SJ, Kim JS
Energy, 141, 2234, 2017 |
| 8 |
Batch grinding kinetics of scrap tire rubber particles in a fluidized-bed jet mill
Xu XF, Li X, Liu FX, Wei W, Wang XJ, Liu KK, Liu ZJ
Powder Technology, 305, 389, 2017 |
| 9 |
Non-catalytic pyrolysis of scrap tires using a newly developed two-stage pyrolyzer for the production of a pyrolysis oil with a low sulfur content
Choi GG, Oh SJ, Kim JS
Applied Energy, 170, 140, 2016 |
| 10 |
Hydrothermal conversion of scrap tire to liquid fuel
Zhang L, Zhou B, Duan PG, Wang F, Xu YP
Chemical Engineering Journal, 285, 157, 2016 |
