1/7/2024 0 Comments Gas escape simulatorNumerical bubble models predict that gas exchange occurs across the bubble rims and a majority of the CH 4 initially present within the bubbles dissolve near the seafloor (Leifer and Patro 2002 McGinnis et al. 2017).Īfter being released from the seafloor, most of the CH 4 contained in bubbles dissolve in the water column as the bubbles ascend toward the sea surface. CH 4 percolating upward is subject to anaerobic oxidation within the sulfate–methane transition zone (Boetius and Wenzhöfer 2013), but in high-velocity fluid flow systems, both dissolved CH 4 and bubbles can bypass this filter (Luff et al. In the light of a rapidly warming Arctic Ocean, it is therefore crucial to understand the transport mechanisms of CH 4 from the seabed through the water column and potentially to the atmosphere in order to estimate the impacts of seafloor CH 4 emissions on the climate and the environment.ĬH 4 in sediments may be present as hydrates, free (bubbles) and/or dissolved gas in pore water. Gaseous CH 4 trapped under hydrate and permafrost caps is presently released through the water column and to the atmosphere on the East Siberian Shelf as the caps become more and more permeable as a result of thawing (Shakhova et al. 2012).Ī substantial amount of CH 4 is also found trapped where permafrost (water ice that is frozen all year) caps exist. 2013), but hydrate dissociation rates may increase as ocean bottom water temperatures increase over human time scales (Ferré et al. Yearly global flux of CH 4 to the atmosphere associated with dissociation of hydrate deposits is presently estimated at 6 Tg, which amounts to less than 1% of the total CH 4 flux to the atmosphere (Kirschke et al. Hydrates are stable under high pressure and low temperature, suggesting that bottom water warming potentially dissociates hydrates at the boundary of their stability (Westbrook et al. They are presently estimated to contain 1800 Gt of carbon (Ruppel and Kessler 2016), equivalent to one sixth of the global mobile carbon pool. Large CH 4 reservoirs in the form of hydrates, a crystalline structure comprising water molecules encapsulating guest molecules such as CO 2 and hydrocarbons (Sloan and Koh 2007), exist in sediments along continental margins worldwide. 2014), because CH 4 is 32 times more potent than CO 2 in terms of warming potential (Pachauri et al. The importance of natural and anthropogenic methane (CH 4) emissions to the atmosphere has been increasingly recognized in the last few decades as CH 4 contributes to greenhouse warming by about 20% (Edenhofer et al. Because of its flexibility, M2PG1 can be applied in a wide variety of environmental settings and future M2PG1 applications may include gas leakage from seafloor installations and bubble injection by wave action. Coupled with numerical ocean circulation and biogeochemical models, M2PG1 could predict the impact of benthic methane emissions on the marine environment and the atmosphere on long time scales and large spatial scales. The model, applied in an Arctic Ocean methane seepage location, showed good agreement with acoustically derived bubble rise heights and in situ sampled methane concentration profiles. Vertical mixing and aerobic oxidation play insignificant roles in environments where advection is important. High salinity increases the rise height of bubbles whereas temperature does not significantly alter it. The parameterization of transfer velocity across bubble rims has the greatest influence on the resulting gas distribution, and bubble sizes are critical for predicting the fate of emitted bubble gas. A model sensitivity analysis elucidates the relative importance of process parameterizations and environmental effects on the gas behavior. Rising, dissolution, and exsolution of a wide size-range of bubbles comprising several gas species are modeled simultaneously with the evolution of the aqueous gas concentrations. The motivation for the model development was to improve the understanding of benthic methane seepage impact on aquatic environments and its effect on atmospheric greenhouse gas composition. We present a marine two-phase gas model in one dimension (M2PG1) resolving interaction between the free and dissolved gas phases and the gas propagation toward the atmosphere in aquatic environments.
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