Reduced gases released from hydrothermal vents supply energy to local deep-marine ecosystems and play an important role in global biogeochemical cycles of sulfur and carbon. The habitable, lower-temperature diffuse flow sites in a hydrothermal system generally have higher biomass than focused flow sites. However, a scarcity of observational data of diffuse flows limits our understanding of the role of volatile gases in these environments. We deployed in situ Raman spectroscopy in the Iheya North hydrothermal field of the mid–Okinawa Trough (East China Sea). A Raman probe inserted directly into hydrothermal vent orifices with temperatures of 30–302 °C collected Raman spectra of hydrothermal fluids. In situ observation data show that the greater volume of diffuse flows results in a flux of volatile gases one to two orders of magnitude higher than that from focused flow environments. This indicates the great potential of diffuse flow for supplying energy and material to hydrothermal systems. The role played by diffuse flow should be reassessed.

Much progress has been achieved in understanding the seafloor hydrogeology, fluid and mineral geochemistry, and microbial biogeochemistry of hydrothermal systems through decades of marine scientific investigations (Von Damm, 1990; Fisher et al., 2007). However, most of this understanding is based on studies conducted at high-temperature focused flow hydrothermal vents (Koschinsky et al., 2008). The more extreme fluid temperatures and eruption conditions of focused flow vents are more likely to draw the attention of researchers. However, compared with focused fluids, diffuse fluids have larger discharge areas, longer subsurface residence times, and more suitable ambient temperatures and flow velocities for microbially mediated biogeochemical transformations (Wankel et al., 2011; Luther et al., 2012). Moreover, heat flux studies indicate that the heat output from diffuse flow is an order of magnitude greater than that from focused flow (Schultz et al., 1992; Bemis et al., 2012). However, observations of volatile component concentrations and their fluxes in hydrothermal diffuse flow are scarce, which greatly limits our understanding of their role in hydrothermal material release fluxes, hydrothermal ecosystem sustenance, and global ocean chemical cycling.

In recent decades, gas-tight fluid sampling has been an effective method of measuring chemical components of hydrothermal fluids and has played a significant role in research on geochemical processes of hydrothermal systems (Seewald et al., 2002). However, gas escape and sulfide precipitation resulting from changes in temperature and pressure during sampling measurement challenge accurate assessment of gas fluxes of hydrothermal systems. New deep-sea in situ observation technology is likely to be the key to advancing hydrothermal system research. High-temperature-resistant electrochemical sensors have obtained dissolved concentrations of H2S and H2 in high-temperature hydrothermal fluids successfully (Ding et al., 2001). The applications of in situ mass spectrometry to hydrothermal volatile gas measurement have revealed that hydrogen is an important energy source for hydrothermal vent symbiosis and that subsurface microbial communities have influence on geochemical fluxes from diffuse hydrothermal fluids (Wankel et al., 2011; Petersen et al., 2011).

In situ Raman spectroscopy is an ideal approach for measuring volatile gases in hydrothermal fluids due to its advantages of being nondestructive and noninvasive and not requiring sample pretreatment (Brewer et al., 2004). We report results from submersible-based deployments of an in situ Raman insertion probe (Brewer et al., 2004; Zhang et al., 2017) to quantify geochemical fluxes of low-temperature diffuse flow sites and high-temperature focused flow sites in the Iheya North hydrothermal field (mid–Okinawa Trough, East China Sea) and to evaluate their contributions to ecosystem sustainability (Fig. 1).

Figure 1.

Photographs of in situ Raman detection of hydrothermal fluids in the Iheya North hydrothermal field (mid–Okinawa Trough, East China Sea). Site 5 (A), site 8 (B), and site 14 (C) are located in the middle-temperature diffuse flow area, high-temperature diffuse flow area, and focused flow area, respectively. (D) Raman insertion probe for hydrothermal vents attached to the robotic arm of the remotely operated vehicle (ROV). (E) The in situ Raman spectrometer inside its titanium pressure housing mounted in ROV Faxian’s tool sled. (F) In situ Raman spectra of hydrothermal fluids collected by the Raman insertion probe. Raman peaks of CO2 (~1280, ~1380 cm−1), CH4 (~2910 cm−1), H2S (~2590 cm−1), and H2O (~1640 cm−1) were used to determine volatile concentration. a.u.—arbitrary units.

Figure 1.

Photographs of in situ Raman detection of hydrothermal fluids in the Iheya North hydrothermal field (mid–Okinawa Trough, East China Sea). Site 5 (A), site 8 (B), and site 14 (C) are located in the middle-temperature diffuse flow area, high-temperature diffuse flow area, and focused flow area, respectively. (D) Raman insertion probe for hydrothermal vents attached to the robotic arm of the remotely operated vehicle (ROV). (E) The in situ Raman spectrometer inside its titanium pressure housing mounted in ROV Faxian’s tool sled. (F) In situ Raman spectra of hydrothermal fluids collected by the Raman insertion probe. Raman peaks of CO2 (~1280, ~1380 cm−1), CH4 (~2910 cm−1), H2S (~2590 cm−1), and H2O (~1640 cm−1) were used to determine volatile concentration. a.u.—arbitrary units.

The Iheya North hydrothermal field is situated at a depth of ~1000 m within the mid–Okinawa Trough, a typical arc–back arc hydrothermal system (Fig. 2). The North Big Chimney is the most active hydrothermal site in the Iheya North hydrothermal field and has the highest temperatures and highest flow rates (Kawagucci et al., 2011). Interstitial water collected from sediment drilled in the Iheya North hydrothermal field during Integrated Ocean Drilling Program (IODP) Expedition 331 suggested that the subseafloor hydrothermal fluid regime was chemically stratified with respect to chloride concentration (Takai et al., 2012).

Figure 2.

Distribution of diffuse sites and focused sites in the North Big Chimney mound, Iheya North hydrothermal field (mid–Okinawa Trough). (A) Map showing location of the Iheya North hydrothermal field. (B) Distribution of sites 1–14 vents in the North Big Chimney mound. (C) Temperature ranges of hydrothermal fluids for sites 1–14 vents. IODP—Integrated Ocean Drilling Program.

Figure 2.

Distribution of diffuse sites and focused sites in the North Big Chimney mound, Iheya North hydrothermal field (mid–Okinawa Trough). (A) Map showing location of the Iheya North hydrothermal field. (B) Distribution of sites 1–14 vents in the North Big Chimney mound. (C) Temperature ranges of hydrothermal fluids for sites 1–14 vents. IODP—Integrated Ocean Drilling Program.

We used a K-type Omega thermocouple with an upper range limit of 650 °C and a precision of 0.75% to measure the temperature of hydrothermal fluids, and used the Raman insertion probe system that was developed on the basis of the Deep Ocean Raman In Situ Spectrometer to determine the composition of hydrothermal fluids in major vents in the North Big Chimney mound, Iheya North hydrothermal field (Fig. 1). Flow rates of focused flow were determined by placing a customized ruler marked with 10 cm intervals vertically on the orifice. For low-velocity diffuse areas, the customized ruler and turbine flow meter were used to determine their flow rates (Ramondenc et al., 2006). The diffuse and focused flow areas were estimated according to the boundary of diffuse and focused flow sites determined through video and the ultrashort baseline positioning system of the remotely operated vehicle (ROV). These in situ measurement processes were carried out mainly in dives 192, 193, and 194 by ROV Faxian during the 2018 cruises of R/V Kexue (Figs. 1A1C). Fourteen (14) hydrothermal vents were selected for in situ measurements; their distribution covers the top, middle, and bottom of the North Big Chimney mound (Fig. 2).

Analysis of In Situ Observations and Measurements

The highest temperature of the hydrothermal fluids in the Iheya North hydrothermal field measured in this study is 302 °C (Fig. S1 in the Supplemental Material1). According to the measured fluid temperatures of 14 survey zones, the temperature of the North Big Chimney mound displays spatial variations over a wide range: the temperature increases from 30 °C at the bottom to a maximum of 302 °C at the top. The low-temperature diffuse flow area covers the majority of the North Big Chimney mound and is found mainly at the mound bottom. The middle-temperature diffuse flow area is located primarily at the middle of the mound and encircles the high-temperature diffuse flow area. The focused flow region is located in a small area at the top of the mound, and the largest focused eruption vent is situated at the highest position of the North Big Chimney mound, with fluid as hot as 302 °C (Figs. 2B and 2C).

The end-member concentrations of CO2, CH4, and H2S at the 14 vents are in the ranges of 12.2–767.1, 3.0–50.9, and 3.6–22.7 mmol/kg, respectively (Fig. S6), indicating that the chemical characteristics of hydrothermal fluids in the North Big Chimney mound vary spatially (Fig. 3; Tables S1 and S2). The in situ observation data reveal that the gas concentrations of low-temperature and middle-temperature diffuse flows are much higher than those of hightemperature diffuse flow and focused flows in the North Big Chimney (Fig. 3). The gas content variation in hydrothermal fluids emitted from vents in the North Big Chimney mound can be explained by subseafloor phase separation. The end-member Cl concentrations for the site 1, 6, and 14 vents are calculated to be 355.0, 427.6, and 661.8 mmol/kg, respectively (Fig. S7). The Cl values of the vent fluid at the site 1 and 6 vents are lower than those of ambient seawater and are accompanied by a higher content of volatiles, suggesting that the fluid was derived from a low-salinity vapor phase produced by phase separation (Foustoukos and Seyfried, 2007). In contrast, the vent fluid at site 14 has a higher Cl value and lower volatile content than ambient seawater, suggesting that the fluid came from the high-salinity brine phase.

Figure 3.

Relationships between fluid temperatures and concentrations of CO2, CH4, and H2S for diffuse sites and focused sites in the North Big Chimney mound, Iheya North hydrothermal field (mid–Okinawa Trough). (A) Temperature ranges of hydrothermal fluids for site 1 to site 14. Red and black dots represent the highest and lowest temperatures measured at the vent, respectively. L-T, M-T, H-T represent low-, medium-, and hightemperature, respectively. (B–D) Concentrations of CO2 (B), CH4 (C), and H2S (D) for North Big Chimney hydrothermal fluids derived from in situ observations.

Figure 3.

Relationships between fluid temperatures and concentrations of CO2, CH4, and H2S for diffuse sites and focused sites in the North Big Chimney mound, Iheya North hydrothermal field (mid–Okinawa Trough). (A) Temperature ranges of hydrothermal fluids for site 1 to site 14. Red and black dots represent the highest and lowest temperatures measured at the vent, respectively. L-T, M-T, H-T represent low-, medium-, and hightemperature, respectively. (B–D) Concentrations of CO2 (B), CH4 (C), and H2S (D) for North Big Chimney hydrothermal fluids derived from in situ observations.

Volatile Flux of the Diffuse Flow and Focused Flow in the North Big Chimney Mound

Based on the analysis of the video images, we estimate that the diffuse venting and focused venting occur over 5%–20% and 1%–5% of the entire area, respectively (Table S3). It is important to clarify that it is difficult to accurately determine the size of the diffuse and focused venting zones, given that these estimates are largely visual and therefore highly subjective. The emission fluxes of CO2, CH4, and H2S are shown in Figure S8, where the fluxes of CO2, CH4, and H2S in the focused flow area are 1.2–5.8 × 109, 7.0–35.0 × 107, and 7.0–35.1 × 107 mol/yr, respectively, while their fluxes in the diffuse flow area are 3.1–12.6 × 1010, 1.4–5.8 × 109, and 9.3–37.0 × 108 mol/yr, respectively. The fluxes of CO2, CH4, and H2S from the diffuse flow are one to two orders of magnitude higher than those from the focused flow.

Geochemical Processes beneath the North Big Chimney Mound

Recent electrical resistivity tomography research of seafloor massive sulfide deposits in the Iheya North hydrothermal field clarified a semilayered resistivity structure, interpreted as that in addition to the sulfide deposits exposed on the seafloor, there is another deep-seated sulfide layer at ~40 m depth below the seafloor (Fig. 2C). A less permeable cap rock layer exists between these two sulfide layers (Ishizu et al., 2019). We speculate that the upwelling CO2-rich hydrothermal fluid in the North Big Chimney mound is trapped under a less permeable cap rock layer, which results in the precipitation and accumulation of massive sulfide deposits below the cap rock (Fig. 2C). When these CO2-rich hydrothermal fluids are ponded and cooled, exsolution and segregation of CO2-rich fluids occurs. For the CO2-rich phase of the H2O-CO2 system, there is a negative correlation between the phase equilibrium temperature and CO2 fraction concentration under the same pressure conditions (Fig. S9) (Dubacq et al., 2013), which explains the negative correlation between the CO2 content and hydrothermal fluid temperatures in the North Big Chimney mound. H2S and CH4 are stripped from the CO2-poor liquid and hence are also enriched in the CO2-rich phase.

Volatile Flux of the Sediment-Associated Hydrothermal System and Arc–Back Arc Hydrothermal System

Our observations show that the proportion of volatiles carried by diffuse flow ranges from ~90% to 95% of the total volatile flux in the North Big Chimney mound, which is attributed to the extensive diffuse flow distribution in the Iheya North hydrothermal field and the high gas volatile content in diffuse flow. The gas contents of arc–back arc hydrothermal fluid are much higher than those of a mid-ocean ridge (MOR) due to the subduction of hydrated oceanic crust and the involvement of felsic magmas (Nakamura and Takai, 2014). In addition, the water depth of arc–back arc hydrothermal vents is usually shallower than that of MOR hydrothermal systems, which makes it easier for phase separation to occur. When CO2-rich hydrothermal fluids undergo CO2 phase exsolution and segregation, the negative correlation between the volatile fraction and equilibrium temperature in the H2O-CO2 equilibrium phase makes the relatively low-temperature diffuse flow more advantageous in terms of volatile component distribution (Dubacq et al., 2013) (Fig. S9).

Sediment-associated hydrothermal fluids generally contain high gas contents due to the thermal decomposition of organic matter. Moreover, microbial methanogenesis occurring in low-temperature sedimentary recharge and discharge zones is also an important source of volatile CH4 in hydrothermal fluids (Proskurowski et al., 2008). Thus, the low-temperature diffuse area of the sediment-associated hydrothermal system has an advantage in the release of volatile gases. Combining these factors, we speculate that the distributions of gas volatile fluxes of the sediment-associated hydrothermal system and the arc–back arc hydrothermal system probably have similar patterns to those in the Iheya North hydrothermal field.

Volatile Flux of the Sediment-Starved Hydrothermal System and MOR Hydrothermal System

The observation data from the Mid-Atlantic Ridge, East Pacific Rise, and Juan de Fuca Ridge suggest that the fraction of heat output attributed to diffuse flow may range from 70% to 95% of the total output (Schultz et al., 1992; Rona and Trivett, 1992; Ramondenc et al., 2006; Shank et al., 1998; Baker et al., 1993; Goto et al., 2007; Mittelstaedt et al., 2012) (Fig. S10). Even in the Lilliput field at 9°33¢S, almost 100% of the heat flux is carried by diffuse flow (Haase et al., 2009). Does the proportion of volatile flux for diffuse and focused flows follow the same rule? Considering that there are common parameters in the calculation of heat flux and volatile flux, we tried to estimate the proportion of volatile flux released by diffuse flow and focused flow using the reported heat flux, fluid temperature, and gas concentration data. Here, we define R as the ratio of heat flux (H) to volatile flux (V); then, we can estimate the ratio of diffuse flow and focused flow in terms of volatile fluxes (see methods in the Supplemental Material). From a large number of previous studies, we searched for data containing the temperature and volatile concentration of both diffuse and focused fluids in the same hydrothermal field. Finally, nine eligible hydrothermal fields (regions) were chosen, and their volatile flux ratios of diffuse flow to focused flow are displayed in Figure 4 (Butterfield and Massoth, 1994; Koschinsky et al., 2002; Lupton et al., 2006; Proskurowski et al., 2008, Craddock, 2009; Foustoukos et al., 2009; Bourbonnais et al., 2012; Reveillaud et al., 2016). As we can see from the statistics of hydrothermal volatiles, nearly half of the volatile flux ratio (Vd/Vf, where d refers to diffuse flow and f refers to focused flow) lies in the 1–10 interval, and the other half of the volatile flux ratios are >10. This indicates that in most hydrothermal regions, the hydrothermal volatile flux of the diffuse flow area is higher than that of the focused flow area, even by one to two orders of magnitude. Although our proposed model for calculating volatile fraction flux ratios is unlikely to be applicable in all hydrothermal regions, available statistics indicate that volatile gases released from low-temperature diffuse flow are probably much higher than those released from high-temperature focused flow on a global scale.

Figure 4.

Hydrothermal volatile flux ratio of diffuse flow to focused flow (Vd/Vf). Fluid temperature and volatile concentration data (H2, CH4, CO2, and H2S) were obtained from the East Pacific Rise (EPR) 9°50′N, the North Fiji Basin, the Manus back-arc basin and North Cleft, the Main Endeavour Field (MEF) and Endeavor segment of the Juan de Fuca Ridge; Piccard and Von Damm of the Mid-Cayman Rise; and northwestern Eifuku of the Mariana Arc. The volatile flux ratio of diffuse flow to focused flow was calculated by assuming that the diffuse flow accounts for 70~90% of hydrothermal heat flux and the focused flow accounts for 10~30% of hydrothermal heat flux. The 70% and 90% in the figure refer to the ratio of the volatile flux calculated by assuming that the diffuse flow accounts for 70% and 90% of the hydrothermal heat flux, respectively.

Figure 4.

Hydrothermal volatile flux ratio of diffuse flow to focused flow (Vd/Vf). Fluid temperature and volatile concentration data (H2, CH4, CO2, and H2S) were obtained from the East Pacific Rise (EPR) 9°50′N, the North Fiji Basin, the Manus back-arc basin and North Cleft, the Main Endeavour Field (MEF) and Endeavor segment of the Juan de Fuca Ridge; Piccard and Von Damm of the Mid-Cayman Rise; and northwestern Eifuku of the Mariana Arc. The volatile flux ratio of diffuse flow to focused flow was calculated by assuming that the diffuse flow accounts for 70~90% of hydrothermal heat flux and the focused flow accounts for 10~30% of hydrothermal heat flux. The 70% and 90% in the figure refer to the ratio of the volatile flux calculated by assuming that the diffuse flow accounts for 70% and 90% of the hydrothermal heat flux, respectively.

The in situ Raman observations of the Iheya North hydrothermal field in the Okinawa Trough back-arc basin indicate that the volatile flux of the diffuse flow is one to two orders of magnitude higher than that of the focused flow, and the phase separation process plays an important role in the distributions of gas volatile fluxes in diffuse flow and focused flow. Considering the fluid characteristics and volatile flux together, we believe that the contribution of diffuse flow in supporting hydrothermal ecosystems is much greater than that of focused flow and that the role played by diffuse flow should be reassessed.

1Supplemental Material. Quantitative assessment method for gas volatile fluxes, Figures S1–S12, and Tables S1–S3. Please visit https://doi.org/10.1130/GEOL.S.21935995 to access the supplemental material, and contact [email protected] with any questions.

We thank the science editor Kathleen Benison and three anonymous reviewers for their prompt work and valuable suggestions. This research was supported by the following grants: the National Natural Science Foundation of China (grants 92058206, 42106184, and 41822604); the Strategic Priority Research Program, Chinese Academy of Sciences (CAS) (grants XDA22050102 and XDA19060402); the Open Fund of the Key Laboratory of Marine Geology and Environment, CAS (grant MGE2021KG06); the Young Taishan Scholars Program (grant tsqn201909158); the China Postdoctoral Science Foundation (grant 2020M682245); the Natural Science Foundation of Shandong Province (grant ZR2021QD046); and the Special Research Assistant Project of CAS.

1.
Baker
,
E.T.
,
Massoth
,
G.J.
,
Walker
,
S.L.
, and
Embley
,
R.W.
,
1993
,
A method for quantitatively estimating diffuse and discrete hydrothermal discharge
:
Earth and Planetary Science Letters
 , v.
118
, p.
235
249
, https://doi.org/10.1016/0012-821X(93)90170-E.
2.
Bemis
,
K.
,
Lowell
,
R.P.
, and
Farough
,
A.
,
2012
,
Diffuse flow: On and around hydrothermal vents at mid-ocean ridges
:
Oceanography (Washington, D.C.)
 , v.
25
, p.
182
191
, https://doi.org/10.5670/oceanog.2012.16.
3.
Bourbonnais
,
A.
, et al
.,
2012
,
Activity and abundance of denitrifying bacteria in the subsurface biosphere of diffuse hydrothermal vents of the Juan de Fuca Ridge
:
Biogeosciences
 , v.
9
, p.
4661
4678
, https://doi.org/10.5194/bg-9-4661-2012.
4.
Brewer
,
P.G.
,
Malby
,
G.
,
Pasteris
,
J.D.
,
White
,
S.N.
,
Peltzer
,
E.T.
,
Wopenka
,
B.
,
Freeman
,
J.
, and
Brown
,
M.O.
,
2004
,
Development of a laser Raman spectrometer for deep-ocean science: Deep-Sea Research
:
Part I, Oceanographic Research Papers
 , v.
51
, p.
739
753
, https://doi.org/10.1016/j.dsr.2003.11.005.
5.
Butterfield
,
D.A.
, and
Massoth
,
G.J.
,
1994
,
Geochemistry of north Cleft segment vent fluids: Temporal changes in chlorinity and their possible relation to recent volcanism
:
Journal of Geophysical Research
 , v.
99
, p.
4951
4968
, https://doi.org/10.1029/93JB02798.
6.
Craddock
,
P.R.
,
2009
,
Geochemical tracers of processes affecting the formation of seafloor hydrothermal fluids and deposits in the Manus back-arc basin
[
Ph.D. thesis
]:
Woods Hole, Massachusetts
,
Massachusetts Institute of Technology–Woods Hole Oceanographic Institution
,
370
p.
7.
Ding
,
K.
,
Seyfried
,
W.E.
, Jr.
,
Tivey
,
M.K.
, and
Bradley
,
A.M.
,
2001
,
In situ measurement of dissolved H2 and H2S in high-temperature hydrothermal vent fluids at the Main Endeavour Field, Juan de Fuca Ridge
:
Earth and Planetary Science Letters
 , v.
186
, p.
417
425
, https://doi.org/10.1016/S0012-821X(01)00257-6.
8.
Dubacq
,
B.
,
Bickle
,
M.J.
, and
Evans
,
K.A.
,
2013
,
An activity model for phase equilibria in the H2O–CO2–NaCl system
:
Geochimica et Cosmochimica Acta
 , v.
110
, p.
229
252
, https://doi.org/10.1016/j.gca.2013.02.008.
9.
Fisher
,
C.R.
,
Takai
,
K.
, and
Le Bris
,
N.
,
2007
,
Hydrothermal vent ecosystems
:
Oceanography (Washington, D.C.)
 , v.
20
, p.
14
23
, https://doi.org/10.5670/oceanog.2007.75.
10.
Foustoukos
,
D.I.
, and
Seyfried
,
W.E.
, Jr.
,
2007
,
Trace element partitioning between vapor, brine and halite under extreme phase separation conditions
:
Geochimica et Cosmochimica Acta
 , v.
71
, p.
2056
2071
, https://doi.org/10.1016/j.gca.2007.01.024.
11.
Foustoukos
,
D.I.
,
Pester
,
N.J.
,
Ding
,
K.
, and
Seyfried
,
W.E.
, Jr.
,
2009
,
Dissolved carbon species in associated diffuse and focused flow hydrothermal vents at the Main Endeavour Field, Juan de Fuca Ridge: Phase equilibria and kinetic constraints
:
Geochemistry, Geophysics, Geosystems
 , v.
10
,
10003
, https://doi.org/10.1029/2009GC002472.
12.
Goto
,
S.
,
Gamo
,
T.
,
Chiba
,
H.
,
Fujioka
,
K.
, and
Mitsuzawa
,
K.
,
2007
,
Contribution of heat outputs from high- and low-temperature hydrothermal sources to the neutrally buoyant plume at the TAG hydrothermal mound, Mid-Atlantic Ridge
:
Earth, Planets, and Space
 , v.
59
, p.
1141
1146
, https://doi.org/10.1186/BF03352057.
13.
Haase
,
K.M.
, et al
.,
2009
,
Diking, young volcanism and diffuse hydrothermal activity on the southern Mid-Atlantic Ridge: The Lilliput field at 9°33′ S
:
Marine Geology
 , v.
266
, p.
52
64
, https://doi.org/10.1016/j.margeo.2009.07.012.
14.
Ishizu
,
K.
,
Goto
,
T.
,
Ohta
,
Y.
,
Kasaya
,
T.
,
Iwamoto
,
H.
,
Vachiratienchai
,
C.
,
Siripunvaraporn
,
W.
,
Tsuji
,
T.
,
Kumagai
,
H.
, and
Koike
,
K.
,
2019
,
Internal structure of a seafloor massive sulfide deposit by electrical resistivity tomography, Okinawa Trough
:
Geophysical Research Letters
 , v.
46
, p.
11,025
11,034
, https://doi.org/10.1029/2019GL083749.
15.
Kawagucci
,
S.
, et al
.,
2011
,
Hydrothermal fluid geochemistry at the Iheya North field in the mid-Okinawa Trough: Implication for origin of methane in subseafloor fluid circulation systems
:
Geochemical Journal
 , v.
45
, p.
109
124
, https://doi.org/10.2343/geochemj.1.0105.
16.
Koschinsky
,
A.
,
Seifert
,
R.
,
Halbach
,
P.
,
Bau
,
M.
,
Brasse
,
S.
, de
Carvalho
,
L.M.
, and
Fonseca
,
N.M.
,
2002
,
Geochemistry of diffuse low-temperature hydrothermal fluids in the North Fiji basin
:
Geochimica et Cosmochimica Acta
 , v.
66
, p.
1409
1427
, https://doi.org/10.1016/S0016-7037(01)00855-9.
17.
Koschinsky
,
A.
,
Garbe-Schönberg
,
D.
,
Sander
,
S.
,
Schmidt
,
K.
,
Gennerich
,
H.-H.
, and
Strauss
,
H.
,
2008
,
Hydrothermal venting at pressure-temperature conditions above the critical point of seawater, 5°S on the Mid-Atlantic Ridge
:
Geology
 , v.
36
, p.
615
618
, https://doi.org/10.1130/G24726A.1.
18.
Lupton
,
J.
, et al
.,
2006
,
Submarine venting of liquid carbon dioxide on a Mariana Arc volcano
:
Geochemistry, Geophysics, Geosystems
 , v.
7
,
Q08007
, https://doi.org/10.1029/2005GC001152.
19.
Luther
,
G.W.
, III
, et al
.,
2012
,
Chemistry, temperature, and faunal distributions at diffuse-flow hydrothermal vents: Comparison of two geologically distinct ridge systems
:
Oceanography (Washington, D.C.)
 , v.
25
, p.
234
245
, https://doi.org/10.5670/oceanog.2012.22.
20.
Mittelstaedt
,
E.
,
Escartín
,
J.
,
Gracias
,
N.
,
Olive
,
J.-A.
,
Barreyre
,
T.
,
Davaille
,
A.
,
Cannat
,
M.
, and
Garcia
,
R.
,
2012
,
Quantifying diffuse and discrete venting at the Tour Eiffel vent site, Lucky Strike hydrothermal field
:
Geochemistry, Geophysics, Geosystems
 , v.
13
,
Q04008
, https://doi.org/10.1029/2011GC003991.
21.
Nakamura
,
K.
, and
Takai
,
K.
,
2014
,
Theoretical constraints of physical and chemical properties of hydrothermal fluids on variations in chemolithotrophic microbial communities in seafloor hydrothermal systems
:
Progress in Earth and Planetary Science
 , v.
1
,
5
, https://doi.org/10.1186/2197-4284-1-5.
22.
Petersen
,
J.M.
, et al
.,
2011
,
Hydrogen is an energy source for hydrothermal vent symbioses
:
Nature
 , v.
476
, p.
176
180
, https://doi.org/10.1038/nature10325.
23.
Proskurowski
,
G.
,
Lilley
,
M.D.
, and
Olson
,
E.J.
,
2008
,
Stable isotopic evidence in support of active microbial methane cycling in low-temperature diffuse flow vents at 9°50′ N East Pacific Rise
:
Geochimica et Cosmochimica Acta
 , v.
72
, p.
2005
2023
, https://doi.org/10.1016/j.gca.2008.01.025.
24.
Ramondenc
,
P.
,
Germanovich
,
L.N.
,
Von Damm
,
K.L.
, and
Lowell
,
R.P.
,
2006
,
The first measurements of hydrothermal heat output at 9°50′ N, East Pacific Rise
:
Earth and Planetary Science Letters
 , v.
245
, p.
487
497
, https://doi.org/10.1016/j.epsl.2006.03.023.
25.
Reveillaud
,
J.
,
Reddington
,
E.
,
McDermott
,
J.
,
Algar
,
C.
,
Meyer
,
J.L.
,
Sylva
,
S.
,
Seewald
,
J.
,
German
,
C.R.
, and
Huber
,
J.A.
,
2016
,
Subseafloor microbial communities in hydrogen-rich vent fluids from hydrothermal systems along the Mid-Cayman Rise
:
Environmental Microbiology
 , v.
18
, p.
1970
1987
, https://doi.org/10.1111/1462-2920.13173.
26.
Rona
,
P.A.
, and
Trivett
,
D.A.
,
1992
,
Discrete and diffuse heat transfer at ASHES vent field, Axial Volcano, Juan de Fuca Ridge
:
Earth and Planetary Science Letters
 , v.
109
, p.
57
71
, https://doi.org/10.1016/0012-821X(92)90074-6.
27.
Schultz
,
A.
,
Delaney
,
J.R.
, and
McDuff
,
R.E.
,
1992
,
On the partitioning of heat flux between diffuse and point source seafloor venting
:
Journal of Geophysical Research
 , v.
97
, p.
12,299
12,314
, https://doi.org/10.1029/92JB00889.
28.
Seewald
,
J.S.
,
Doherty
,
K.W.
,
Hammar
,
T.R.
, and
Liberatore
,
S.P.
,
2002
,
A new gas-tight isobaric sampler for hydrothermal fluids: Deep-Sea Research
:
Part I, Oceanographic Research Papers
 , v.
49
, p.
189
196
, https://doi.org/10.1016/S0967-0637(01)00046-2.
29.
Shank
,
T.M.
,
Fornari
,
D.J.
,
Von Damm
,
K.L.
,
Lilley
,
M.D.
,
Haymon
,
R.M.
, and
Lutz
,
R.A.
,
1998
,
Temporal and spatial patterns of biological community development at nascent deep-sea hydrothermal vents (9°50′N, East Pacific Rise): Deep-Sea Research
:
Part II, Topical Studies in Oceanography
 , v.
45
, p.
465
515
, https://doi.org/10.1016/S0967-0645(97)00089-1.
30.
Takai
,
K.
,
Mottl
,
M.J.
, and
Nielsen
,
S.H.
,
2012
,
IODP Expedition 331: Strong and expansive subseafloor hydrothermal activities in the Okinawa Trough
:
Scientific Drilling
 , v.
13
, p.
19
27
, https://doi.org/10.5194/sd-13-19-2012.
31.
Von Damm
,
K.L.
,
1990
,
Seafloor hydrothermal activity: Black smoker chemistry and chimneys
:
Annual Review of Earth and Planetary Sciences
 , v.
18
, p.
173
204
, https://doi.org/10.1146/annurev.ea.18.050190.001133.
32.
Wankel
,
S.D.
,
Germanovich
,
L.N.
,
Lilley
,
M.D.
,
Genc
,
G.
,
DiPerna
,
C.J.
,
Bradley
,
A.S.
,
Olson
,
E.J.
, and
Girguis
,
P.R.
,
2011
,
Influence of subsurface biosphere on geochemical fluxes from diffuse hydrothermal fluids
:
Nature Geoscience
 , v.
4
, p.
461
468
, https://doi.org/10.1038/ngeo1183.
33.
Zhang
,
X.
, et al
.,
2017
,
Development of a new deep-sea hybrid Raman insertion probe and its application to the geochemistry of hydrothermal vent and cold seep fluids: Deep-Sea Research
:
Part I, Oceanographic Research Papers
 , v.
123
, p.
1
12
, https://doi.org/10.1016/j.dsr.2017.02.005.
Gold Open Access: This paper is published under the terms of the CC-BY license.