| 21 |
Enhanced methane recovery from low-concentration coalbed methane by gas hydrate formation in graphite nanofluids
Yan J, Lu YY, Zhong DL, Zou ZL, Li JB
Energy, 180, 728, 2019 |
| 22 |
Hydrate-liquid-vapor equilibrium condition of N-2 + CO2 + H2O system: Measurement and modeling
Jarrahian A, Nakhaee A
Fuel, 237, 769, 2019 |
| 23 |
Molecular level investigations and stability analysis of mixed methane-tetrahydrofuran hydrates: Implications to energy storage
Kumar A, Veluswamy HP, Linga P, Kumar R
Fuel, 236, 1505, 2019 |
| 24 |
Experimental and modelling studies on the effects of nanofluids (SiO2, Al2O3, and CuO) and surfactants (SDS and CTAB) on CH4 and CO2 clathrate hydrates formation
Pahlavanzadeh H, Khanlarkhani M, Rezaei S, Mohammadi AH
Fuel, 253, 1392, 2019 |
| 25 |
Gas hydrate formation probability distributions: Induction times, rates of nucleation and growth
Metaxas PJ, Lim VWS, Booth C, Zhen J, Stanwix PL, Johns ML, Aman ZM, Haandrikman G, Crosby D, May EF
Fuel, 252, 448, 2019 |
| 26 |
Hydrate formation management simulations with anti-agglomerants and thermodynamic inhibitors in a subsea tieback
Wang Y, Koh CA, White J, Patel Z, Zerpa LE
Fuel, 252, 458, 2019 |
| 27 |
Insights into the phase behaviour of tetra-n-butyl ammonium bromide semi-clathrates formed with CO2, (CO2 + CH4) using high-pressure DSC
Yan J, Lu YY, Zhong DL, Qing SL
Journal of Chemical Thermodynamics, 137, 101, 2019 |
| 28 |
Synergistic effect of salts and methanol in thermodynamic inhibition of sII gas hydrates
Semenov AP, Stoporev AS, Mendgaziev RI, Gushchin PA, Khlebnikov VN, Yakushev VS, Istomin VA, Sergeeva DV, Vinokurov VA
Journal of Chemical Thermodynamics, 137, 119, 2019 |
| 29 |
THERMOGENIC PETROLEUM POTENTIAL OF THE NANKAI SUBDUCTION ZONE, OFFSHORE SW JAPAN
Shiraishi K, Yamada Y, Nibe T
Journal of Petroleum Geology, 42(4), 417, 2019 |
| 30 |
Universal correlation for gas hydrates suppression temperature of inhibited systems: II. Mixed salts and structure type
Hu Y, Lee BR, Sum AK
AIChE Journal, 64(6), 2240, 2018 |
