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Origin of salt-enriched pore fluids in the northern Gulf of Mexico (2007)

Reitz, Anja ; Haeckel, Matthias ; Wallmann, Klaus ; [weitere]

Elsevier

In: Earth and Planetary Science Letters, 259 (3/4). pp. 266-282.

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Publikationsdatum: 2019-09-23

Beschreibung: Pore fluids from the Green Canyon Block in the northern Gulf of Mexico show distinct differences with respect to element concentrations and oxygen, hydrogen, and strontium isotope signatures. The shallowest of the three investigated sites (GC185 or Bush Hill at 540 m water depth) is interpreted as a seafloor piercing mud mound and the two deeper areas (GC415 East and West at 950 and 1050 m water depth) as gas vent and oil seep sites. All three locations accommodate near-surface gas hydrates and the sediment surface is populated with chemosynthetic communities. They are characterized by a distinct increase in salinity with depth. However, the origin of this increasing salinity is different for the GC415 sites and Bush Hill and the depth source of the fluids is considerably different for all sites. The more saline fluids of the GC415 sites result from the dissolution of halite by formation water from two different sources. The fluids of GC415 East have most likely a deeper origin (early Cenozoic or even Mesozoic) and experienced elevated temperatures leading to mineral/water reactions including mineral transformations (e.g. smectite to illite transformation) and dissolution (e.g. feldspar dissolution). This process is expressed by the heavier oxygen isotope values and distinct Li, Sr, and Ca enrichments. The fluids of GC415 West have a shallower origin which is expressed by a smaller enrichment in Li, Sr, and Ca and lighter oxygen isotopes. The fluids from Bush Hill are less saline and its fluid signature indicates intensive water/mineral interaction. Oxygen and hydrogen isotope values as well as Na/Cl and Br/Cl molar ratios suggest that the salt enrichment was caused by phase separation under sub-critical conditions. A simple heat flow model simulation suggests that sub-critical phase separation may have occurred at a depth of ∼ 1650 m at ∼ 350 °C.

Materialart: Article , PeerReviewed

Format: text

DOI: 10.1016/j.epsl.2007.04.037

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Bubble-induced porewater mixing: a 3-D model for deep porewater irrigation (2007)

Haeckel, Matthias ; Boudreau, B. P. ; Wallmann, Klaus

Elsevier

In: Geochimica et Cosmochimica Acta, 71 (21). pp. 5135-5154.

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Publikationsdatum: 2017-09-08

Beschreibung: Porewater data from vent sites of the northeastern shelf off Sakhalin Island, Sea of Okhotsk, exhibit bottom-water concentrations down to a sediment depth of up to 300 cm. Below this depth, solute concentrations rapidly change due to methanogenesis and anaerobic methane oxidation (AMO). The profile shapes suggest an irrigation-like process that mixes on a meter scale. At these sites active gas emanation into the overlying water column and near-surface gas hydrates are commonly observed. We propose that methane gas bubbles rise through the soft surface sediments and cause mixing of the porewater. Mathematically, the bubble-induced irrigation can be described by eddy diffusion enhancing the diffusive transport of solutes by several orders of magnitude. A 3-D numerical transport-reaction model was developed to investigate the parameters defining the mixing process, such as bubble rise velocity, tube size, tube distribution in the sediment, and ebullition frequency. Model consistency with the field data requires eddy diffusivities ⩾1 × 105 cm2/a, tube densities of 〉4 tubes/m2 (equivalent to a tube spacing of 〈40 cm), active gas seepage for more than a few weeks or months, and moderate to low diagenetic reaction rates of solutes. The corresponding methane gas fluxes that are predicted from the results of the model realizations range from 1 × 103–5 × 105 L/(m2 a). Due to bubble mixing, solute fluxes in these sediments are increased by a factor of 3 and the maximum AMO rate by a factor of 7.

Materialart: Article , PeerReviewed

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DOI: 10.1016/j.gca.2007.08.011

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In-situ hydrocarbon concentrations from pressurized cores in surface sediments, Northern Gulf of Mexico (2007)

Heeschen, Katja U. ; Hohnberg, Hans Jürgen ; Haeckel, Matthias ; [weitere]

Elsevier

In: Marine Chemistry, 107 (4). pp. 498-515.

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Publikationsdatum: 2017-08-22

Beschreibung: Two newly developed coring devices, the Multi-Autoclave-Corer and the Dynamic Autoclave Piston Corer were deployed in shallow gas hydrate-bearing sediments in the northern Gulf of Mexico during research cruise SO174 (Oct–Nov 2003). For the first time, they enable the retrieval of near-surface sediment cores under ambient pressure. This enables the determination of in situ methane concentrations and amounts of gas hydrate in sediment depths where bottom water temperature and pressure changes most strongly influence gas/hydrate relationships. At seep sites of GC185 (Bush Hill) and the newly discovered sites at GC415, we determined the volume of low-weight hydrocarbons (C1 through C5) from nine pressurized cores via controlled degassing. The resulting in situ methane concentrations vary by two orders of magnitudes between 0.031 and 0.985 mol kg− 1 pore water below the zone of sulfate depletion. This includes dissolved, free, and hydrate-bound CH4. Combined with results from conventional cores, this establishes a variability of methane concentrations in close proximity to seep sites of five orders of magnitude. In total four out of nine pressure cores had CH4 concentrations above equilibrium with gas hydrates. Two of them contain gas hydrate volumes of 15% (GC185) and 18% (GC415) of pore space. The measurements prove that the highest methane concentrations are not necessarily related to the highest advection rates. Brine advection inhibits gas hydrate stability a few centimeters below the sediment surface at the depth of anaerobic oxidation of methane and thus inhibits the storage of enhanced methane volumes. Here, computerized tomography (CT) of the pressure cores detected small amounts of free gas. This finding has major implications for methane distribution, possible consumption, and escape into the bottom water in fluid flow systems related to halokinesis.

Materialart: Article , PeerReviewed

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DOI: 10.1016/j.marchem.2007.08.008

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