| 1 |
Enhanced separation of coal bed methane via bioclathrates formation
Sun Q, Chen B, Li YY, Yuan GQ, Xu Z, Guo XQ, Li XX, Lan WJ, Yang LY
Fuel, 243, 10, 2019 |
| 2 |
Characterizations of pore, mineral and petrographic properties of marine shale using multiple techniques and their implications on gas storage capability for Sichuan Longmaxi gas shale field in China
Xu H, Zhou W, Zhang R, Liu SM, Zhou QM
Fuel, 241, 360, 2019 |
| 3 |
Experimental study on CO2 hydrate formation in the presence of TiO2, SiO2, MWNTs nanoparticles
Li AR, Luo D, Jiang LL, Wang J, Zhou Y
Separation Science and Technology, 54(15), 2498, 2019 |
| 4 |
Energy-efficient storage of methane in the formed hydrates with metal nanoparticles-grafted carbon nanotubes as promoter
Song YM, Wang F, Guo G, Luo SJ, Guo RB
Applied Energy, 224, 175, 2018 |
| 5 |
Promotion effects of mung starch on methane hydrate formation equilibria/rate and gas storage capacity
Sun Q, Chen B, Li YY, Xu Z, Guo XQ, Li XX, Lan WJ, Yang LY
Fluid Phase Equilibria, 475, 95, 2018 |
| 6 |
Methane sorption and storage characteristics of organic-rich carbonaceous rocks, Lurestan province, southwest Iran
Shabani M, Moallemi SA, Krooss BM, Amann-Hildenbrand A, Zamani-Pozveh Z, Ghalavand H, Littke R
International Journal of Coal Geology, 186, 51, 2018 |
| 7 |
Identification of conditions for increased methane storage capacity in sII and sH clathrate hydrates from Monte Carlo simulations
Papadimitriou NI, Tsimpanogiannis IN, Economou IG, Stubos AK
Journal of Chemical Thermodynamics, 117, 128, 2018 |
| 8 |
Experimental study and thermodynamic modeling of CO2 gas hydrate formation in presence of zinc oxide nanoparticles
Mohammadi M, Haghtalab A, Fakhroueian Z
Journal of Chemical Thermodynamics, 96, 24, 2016 |
