Manganese and methane in hydrothermal plumes along the East Pacific Rise, 8°40′ to 11°50′N

Mottl, Michael J.; Sansone, Francis J.; Wheat, C. Geoffrey; Resing, J. A.; Baker, Edward T.; Lupton, J. E.

doi:10.1016/0016-7037(95)00245-u

Cited by 61 publications

(71 citation statements)

References 54 publications

(63 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…All the profiles displayed peak concentrations around 2600 m, about 150 m above seafloor, which is comparable to the previous results reported by Wang et al (2012). Compared with previous reported data from venting systems at other spreading ridges, it is interested to be noticed that the H 2 and CH 4 concentrations of the Dragon Flag hydrothermal filed are intermediate in the global series (Lilley et al 1995;Mottl et al 1995;Bougault et al 1998;Bennett et al 2013). CH 4 : Mn ratios at plume height can be used as an indication of "end-member" vent type (Charlou et al 1991;Mottl et al 1995;German et al 2010b).…”

Section: Wang Et Alsupporting

confidence: 79%

“…Compared with previous reported data from venting systems at other spreading ridges, it is interested to be noticed that the H 2 and CH 4 concentrations of the Dragon Flag hydrothermal filed are intermediate in the global series (Lilley et al 1995;Mottl et al 1995;Bougault et al 1998;Bennett et al 2013). CH 4 : Mn ratios at plume height can be used as an indication of "end-member" vent type (Charlou et al 1991;Mottl et al 1995;German et al 2010b). Combining the CH 4 data in this article and our Mn data (not published), the CH 4 : Mn ratios in Dragon Flag hydrothermal plume were < 1.…”

Section: Wang Et Almentioning

confidence: 99%

“…However, it is hard to analyze H 2 and CH 4 simultaneously by only one type of GC because of the chromatographic differences between H 2 and CH 4 . Generally, CH 4 is analyzed by a GC equipped with a flame ionization detector (FID), which only responds to organic gases, or a thermal conductivity detector (TCD) in combination with a headspace or a purge-trap technique to enrich CH 4 (Mottl et al 1995;Charlou et al 1998;Radford-Knoery et al 1998;Connelly et al 2007;Love et al 2008); H 2 is usually measured by a GC equipped with a pulsed discharge helium ionization detector (PDHID) or reduction gas detector, which cannot analyze CH 4 , combined with headspace technique, (Kelley et al 1998;Kawagucci et al 2010;Marbler et al 2010). A GC with a TCD can determine H 2 and CH 4 concentrations simultaneously at high concentration levels, for example, for hydrothermal vent fluid samples, but not at the low concentrations found in hydrothermal plumes or seawater, about several nM dozens of nM.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Development and application of a gas chromatography method for simultaneously measuring H₂ and CH₄ in hydrothermal plume samples

Wang

Zhou

Qinye

et al. 2015

Limnology & Ocean Methods

View full text Add to dashboard Cite

A robust, simple and efficient gas chromatography (GC) method is presented for determining H 2 and CH 4 concentrations simultaneously in water samples. The GC system consists of one detector (pulsed discharge helium ionization detector-PDHID), two columns in two ovens, respectively, and two 2-position-6-port purge valves. In this method, H 2 and CH 4 in water samples were first extracted into the headspace of syringes, then injected into the GC system. Both H 2 and CH 4 were detected by a PDHID. The separation of CH 4 from O 2 and N 2 in seawater is achieved by switching the O 2 and N 2 out of the carrier gas flow at the appropriate time window. H 2 and CH 4 concentrations in water samples collected from hydrothermal plumes at the Southwest Indian Ridge were determined successfully using this method.

show abstract

Section: Wang Et Alsupporting

confidence: 79%

Section: Wang Et Almentioning

confidence: 99%

mentioning

confidence: 99%

See 1 more Smart Citation

Development and application of a gas chromatography method for simultaneously measuring H₂ and CH₄ in hydrothermal plume samples

Wang

Zhou

Qinye

et al. 2015

Limnology & Ocean Methods

View full text Add to dashboard Cite

show abstract

“…However, the collected venting fluids ( max = 328 ∘ C) from the Yonaguni Knoll IV hydrothermal field in the southern Okinawa Trough had a wide range of chemical compositions (e.g., Cl − 376-635 mmol kg −1 ; Ca 2+ 14.3-26.1 mmol kg −1 ; Mn 2+ 0.70-1.25 mmol kg −1 ), which is considered as evidence for subseafloor phase separation [14]. Furthermore, Mn 2+ has also been studied extensively (e.g., [15][16][17]), and the distribution of Mn 2+ in the seawater column is strongly affected by external sources and sinks, hydrothermal processes, and redox condition (e.g., [17][18][19][20][21][22][23][24]). …”

Section: Introductionmentioning

confidence: 99%

Understanding the Compositional Variability of the Major Components of Hydrothermal Plumes in the Okinawa Trough

et al. 2018

View full text Add to dashboard Cite

Studies of the major components of hydrothermal plumes in seafloor hydrothermal fields are critical for an improved understanding of biogeochemical cycles and the large-scale distribution of elements in the submarine environment. The composition of major components in hydrothermal plume water column samples from 25 stations has been investigated in the middle and southern Okinawa Trough. The physical and chemical properties of hydrothermal plume water in the Okinawa Trough have been affected by input of the Kuroshio current, and its influence on hydrothermal plume water from the southern Okinawa Trough to the middle Okinawa Trough is reduced. The anomalous layers of seawater in the hydrothermal plume water columns have higher K + , Ca 2+ , Mn 2+ , B 3+ , Ca 2+ /SO 4 2− , and Mn 2+ /Mg 2+ ratios and higher optical anomalies than other layers. The Mg 2+ , SO 4 2− , Mg 2+ /Ca 2+ , and SO 4 2− /Mn 2+ ratios of the anomalous layers are lower than other layers in the hydrothermal plume water columns and are consistent with concentrations in hydrothermal vent fluids in the Okinawa Trough. This suggests that the chemical variations of hydrothermal plumes in the Tangyin hydrothermal field, like other hydrothermal fields, result in the discharge of high K + , Ca 2+ , and B 3+ and low Mg 2+ and SO 4 2− fluid. Furthermore, element ratios (e.g., Sr 2+ /Ca 2+ , Ca 2+ /Cl − ) in hydrothermal plume water columns were found to be similar to those in average seawater, indicating that Sr 2+ /Ca 2+ and Ca 2+ /Cl − ratios of hydrothermal plumes might be useful proxies for chemical properties of seawater. The hydrothermal K + , Ca 2+ , Mn 2+ , and B 3+ flux to seawater in the Okinawa Trough is about 2.62-873, 1.04-326, 1.30-76.4, and 0.293-34.7 × 10 6 kg per year, respectively. The heat flux is about 0.159-1,973 × 10 5 W, which means that roughly 0.0006% of ocean heat is supplied by seafloor hydrothermal plumes in the Okinawa Trough.

show abstract

“…While in some areas this maximum may be the result of horizontal advection from methane-rich source regions (Scranton and Farrington 1977;Brooks 1979;Sansone et al 1999) or from coastal upwelling (Rehder et al 2002), the majority of researchers have attributed this supersaturation to in situ methane production (e.g., Scranton and Brewer 1977;Conrad and Seiler 1988;Holmes et al 2000). Supersaturation of methane in deep ocean waters can occur as a result of hydrothermal discharge (e.g., de Angelis et al 1993;Mottl et al 1995;Cowen et al 2002), release of methane-rich pore waters (e.g., Reeburgh 1976;Scranton and Farrington 1977), or seepage from hydrates (Suess et al 1999) or other gas reserves (Brooks 1979).…”

mentioning

confidence: 99%

Methane along the western Mexican margin

Sansone¹,

Graham²,

Berelson³

2004

Limnology & Oceanography

Self Cite

View full text Add to dashboard Cite

We investigated the processes controlling the water-column and sediment methane distributions at 14 stations along the western Mexican margin, in and around the Gulf of California. Stations were grouped into two categories: coastal basins and open margins. Diffusive methane fluxes from the sediment at all sites, as estimated from sediment methane gradients, were 0.24-5.5 mol m Ϫ2 d Ϫ1 , with the highest fluxes observed on the Pacific margin of Baja California at both basin and open-margin sites. These high rates occur despite the lack of significant terrestrial input to these sediments, reflecting the importance of upwelling-induced productivity. Methane concentrations in the upper water column were supersaturated with respect to the present atmosphere at all sites, with sea-air fluxes of methane of 0.5-5.9 mol m Ϫ2 d Ϫ1 .Four of the open-margin sites had seafloor depths extending below the oxygen minimum zone (ϳ400-800 m) and contained low methane concentrations below the subsurface methane maximum. The remaining margin site was shallow (593 m), with a seafloor that intersected the oxygen minimum zone, and had elevated methane concentrations throughout the water column; this indicates that such sediments may be a significant source of methane to the eastern tropical North Pacific (ETNP). The seawater within silled basin sites also had supersaturated methane concentrations, reflecting the anoxic conditions within the basins. However, methane levels were low at the sill depth, indicating that the silled basins were unlikely to be significant sources of methane to the ETNP. We observed an inverse relationship between methane concentration and ␦ 13 C-CH 4 value in the basin waters, consistent with biological aerobic oxidation of methane being released from the sediment; an apparent kinetic isotopic fractionation factor of 1.0100-0.0038 was calculated for this process. Isotopically heavy methane resulting from similar oxidation of seafloor-derived methane may be the source of large pools of heavy methane previously observed offshore in the ETNP.Methane is a potent greenhouse gas and an important component of atmospheric chemical cycles. The concentration of methane in the atmosphere has more than doubled (700 ppb to Ͼ1,750 ppb) over the last 250 yr and is now increasing at a rate of ϳ2% per year (Cicerone and Oremland 1988; IPCC 2001;Steele et al. 2002), implying that in the near future, methane could have a larger role in global warming and atmospheric chemistry than it does today.While the open ocean appears to be a relatively small source of methane to the atmosphere (e.g., Breas et al. 2001), methane cycling in the open ocean is not fully understood. Additionally, coastal areas and other marine environments rich in methane are significant sources to the atmosphere (e.g., Owens et al. 1991;Bange et al. 1994; Sansone et al. 1998b;Oudot et al. 2002). Understanding the natural sources and sinks of methane is vital to determining future changes in atmospheric methane concentrations.1 Corresponding author (sa...

show abstract

Manganese and methane in hydrothermal plumes along the East Pacific Rise, 8°40′ to 11°50′N

Cited by 61 publications

References 54 publications

Development and application of a gas chromatography method for simultaneously measuring H₂ and CH₄ in hydrothermal plume samples

Development and application of a gas chromatography method for simultaneously measuring H₂ and CH₄ in hydrothermal plume samples

Understanding the Compositional Variability of the Major Components of Hydrothermal Plumes in the Okinawa Trough

Methane along the western Mexican margin

Contact Info

Product

Resources

About

Manganese and methane in hydrothermal plumes along the East Pacific Rise, 8°40′ to 11°50′N

Cited by 61 publications

References 54 publications

Development and application of a gas chromatography method for simultaneously measuring H2 and CH4 in hydrothermal plume samples

Development and application of a gas chromatography method for simultaneously measuring H2 and CH4 in hydrothermal plume samples

Understanding the Compositional Variability of the Major Components of Hydrothermal Plumes in the Okinawa Trough

Methane along the western Mexican margin

Contact Info

Product

Resources

About

Development and application of a gas chromatography method for simultaneously measuring H₂ and CH₄ in hydrothermal plume samples

Development and application of a gas chromatography method for simultaneously measuring H₂ and CH₄ in hydrothermal plume samples