Add to ORKGA home-made static NMR cell with pressure up to 10 MPa was employed to observe the formation and dissociation processes of methane hydrate by in situ H-1 and C-13 NMR spectroscopies. Methane hydrate can be formed or decomposed in the temperature range of -5 to -13 degrees C at pressures between 4.0 and 7.0 MPa. The higher methane pressure, the formation or dissociation temperature of methane hydrate was higher. In situ H-1 NMR experiments indicated that the critical size of the hydrate clusters is crucial for the formation of methane hydrate
Highlights • Methane hydrate formation was studied by low-field NMR technology under formation...
We performed rapid depressurization experiments on methane hydrate under isothermal conditions above...
Gas hydrates represent an attractive way of storing large quantities of gas such as methane and carb...
The dynamics of methane hydrate growth and decomposition were studied by nuclear magnetic resonance ...
The reformation of methane-ethane hydrate was observed in situ using 13C MAS NMR spectroscopy. In al...
The dissociation behavior of the CH4+CO2 binary gas hydrate has been investigated using Nuclear Magn...
The dissociation behavior of the CH4+CO2 binary gas hydrate has been investigated using Nuclear Magn...
13C NMR spectroscopic analysis was carried out to clarify the formed hydrate structure in specific c...
Natural gas hydrates provide both a flow- assurance hazard and a potential fossil fuel source. In or...
Methane hydrate nucleation and growth from a bulk phase has been investigated using a quiescent high...
Solid State NMR spectroscopy has taken a very prominent place among the many spectroscopic technique...
Stability condition is of critical importance for methane hydrate exploitation, transportation, and ...
In situ Raman spectroscopy is employed to study the phase behavior of methane hydrate at high pressu...
This paper reports formation and dissociation patterns of methane hydrate in sandstone. Magnetic res...
AbstractThe structural stability of methane hydrate under pressure at room temperature was examined ...
Highlights • Methane hydrate formation was studied by low-field NMR technology under formation...
We performed rapid depressurization experiments on methane hydrate under isothermal conditions above...
Gas hydrates represent an attractive way of storing large quantities of gas such as methane and carb...
The dynamics of methane hydrate growth and decomposition were studied by nuclear magnetic resonance ...
The reformation of methane-ethane hydrate was observed in situ using 13C MAS NMR spectroscopy. In al...
The dissociation behavior of the CH4+CO2 binary gas hydrate has been investigated using Nuclear Magn...
The dissociation behavior of the CH4+CO2 binary gas hydrate has been investigated using Nuclear Magn...
13C NMR spectroscopic analysis was carried out to clarify the formed hydrate structure in specific c...
Natural gas hydrates provide both a flow- assurance hazard and a potential fossil fuel source. In or...
Methane hydrate nucleation and growth from a bulk phase has been investigated using a quiescent high...
Solid State NMR spectroscopy has taken a very prominent place among the many spectroscopic technique...
Stability condition is of critical importance for methane hydrate exploitation, transportation, and ...
In situ Raman spectroscopy is employed to study the phase behavior of methane hydrate at high pressu...
This paper reports formation and dissociation patterns of methane hydrate in sandstone. Magnetic res...
AbstractThe structural stability of methane hydrate under pressure at room temperature was examined ...
Highlights • Methane hydrate formation was studied by low-field NMR technology under formation...
We performed rapid depressurization experiments on methane hydrate under isothermal conditions above...
Gas hydrates represent an attractive way of storing large quantities of gas such as methane and carb...