Methane hydrate stability in pore water: A simple theoretical approach for geophysical applications

Abstract

Geophysicists have recently expressed an interest in understanding how pore water composition affects CH₄ hydrate stability conditions in the marine environment. It has previously been shown in the chemical engineering literature that CH₄ hydrate stability conditions in electrolyte solutions are related to the activity of water (a_w). Here we present additional experimental data in support of this relationship and then use the relationship to address issues relevant to geophysicists. Pressure and temperature conditions of CH₄ hydrate dissociation were determined for 10 solutions containing variable concentrations of Cl⁻, SO₄²⁻ Br⁻, Na⁺, K⁺, Mg²⁺, NH₄⁺, and Cu²⁺. The reciprocal temperature offset of CH₄ hydrate dissociation between the CH₄‐pure water system and each of these solutions (and for other electrolyte solutions in literature) is directly related to the logarithm of the activity of water (lna_w). Stability conditions for CH₄ hydrate in any pore water system therefore can be predicted simply and accurately by calculating lna_w. The effect of salinity variation and chemical diagenesis on CH₄ hydrate stability conditions in the marine environment can be evaluated by determining how these processes affect lna_w of pore water.