Analysis of the effect of hydrate on water retention curves in gas hydrate-bearing sediments using gas drainage combined with NMR

Water retention curves play a critical role in numerical simulations for predicting fluid production and sediment deformation behaviors in gas hydrate-bearing sediments (GHBSs). This study uses a new testing assembly that combines gas drainage and low-field nuclear magnetic resonance (NMR) tests to determine the water retention curves of artificially synthesized clay silty specimens. The effect of hydrate on the pore size distributions and water retention curves is analyzed via NMR transverse relaxation time curve distributions, and the mechanism of changes in the water retention curve parameters is further discussed. The results show that hydrate formation decreases the proportion of pores with sizes greater than 15 mu m and increases the proportion of pores with sizes less than 3.5 mu m in clay silty sediments. Hydrate formation increases capillary pressure and prevents available water migration. The presence of hydrate exponentially increases the normalized capillary pressure but exponentially decreases the normalized curve shape factor, yielding narrower curve distributions. The gas entry pressure and curve shape factor exhibit linear correlations with the pore size distribution parameters. The results imply that the changes in the water retention curves are strongly related to the initial pore size distributions. This study offers a deep understanding of capillary effects-related water retention characteristics and their underlying links with the pore size distributions, and demonstrates that low-field NMR has great potential for characterizing water retention curves of GHBSs.

Automated summary

Water retention curves of clay silty specimens with hydrate formation are determined using a new testing assembly combining gas drainage and low-field NMR tests. The effects of hydrate on the pore size distributions and water retention curves are analyzed and discussed. Results show that hydrate formation changes the pore characteristics and affects water retention curves. This study offers a deep understanding of the relationship between capillary effects-related water retention characteristics and pore size distributions and demonstrates the potential of low-field NMR for characterizing water retention curves of gas hydrate-bearing sediments.