Abstract
Seafloor hydrothermal mineralization of four active hydrothermal fields (Snail, Yamanaka, Archaean and Pika sites) in the Southern Mariana Trough was investigated to clarify the mineralogical and geochemical characteristics of the hydrothermal minerals. The Snail site and the Yamanaka site are located on the crest of the backarc spreading ridge (on-axis). The Pika site sits atop an off-axial volcano, 4.9 km distant from the spreading axis, while the Archaean site sits on the flank of the spreading ridge, about 1.5 km distant from the axis. In the four hydrothermal sites, chimney and mound sulfides are composed mainly of pyrite, marcasite, sphalerite and chalcopyrite. Conduits and interstices of these sulfide minerals are filled with late barite and anhydrite. Mineralizations of off-axial hydrothermal fields have mineralogical and geochemical signatures (Fe-rich and low fS2 condition) similar to those of mineralizations at sediment-free mid-ocean ridge settings. By contrast, mineralizations of on-axial sites show distinctly Zn and Pb-rich (high fS2 condition) signatures similar to those found in arc or rifting settings. Sulfur isotopic compositions of collected sulfide minerals show a similar diversity with a mid-ocean ridge range for the off-axial sites and an island-arc range for the on-axial sites. These isotopic signatures could be explained by varying proportions of magmatic sulfur leached from the underlying volcanic rocks and reduced seawater sulfates.
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1 Introduction
Modern seafloor hydrothermal mineralization is mainly found in three types of environments: at mid-ocean ridges, at intraoceanic arc-backarc systems such as the Mariana Trough, and at intracontinental arc-backarc systems such as the Okinawa Trough (Herzig and Hannington 1995; Herzig et al. 2002). Seafloor massive sulfides formed in the subduction-related arc and backarc environments have attracted the attention of economic geologists since these hydrothermal fields are considered to be modern analogues of volcanogenic massive sulfide deposits on land (e.g., Fouquet et al. 1993). Detailed geophysical, geomorphological, geological, mineralogical, geochemical and microbiological analyses of seafloor hydrothermal systems in the Southern Mariana Trough have been carried out within the past 20 years (e.g., Fryer 1995; Ishibashi and Urabe 1995; Ishibashi et al. 2006; Kakegawa et al. 2008; Kato et al. 2009; Yoshikawa et al. 2012; Nakamura et al. 2013; Takamasa et al. 2013; Ishibashi et al. Chap. 23). In this area, five active hydrothermal fields lie in three different geological environments (Fig. 22.1). The Snail and Yamanaka sites are located on the crest of the backarc-spreading ridge (on-axis), while the Pika and Urashima sites are on an off-axis knoll (volcano). The Archaean site lies on the flank of the backarc spreading ridge. The linear array of hydrothermal activities at Snail, Archaean and Pika sites which is almost perpendicular to the arc trend may be related to a structural lineament, although there is no visible tectonic feature connecting them in this area. Yoshikawa et al. (2012) investigated the five hydrothermal sites using near-bottom swath mapping data by the autonomous underwater vehicle URASHIMA and dive observation data by the submersible SHINKAI 6500. They indicated that the two on-axis sites (Snail and Yamanaka) represent locations of local activity associated with a 4th order spreading segment-scale diking event, in contrast, the three off-axis sites (Archaean, Pika and Urashima) represent locations of sustained large-scale hydrothermal activity related to an off-axis upwelling magma system. Previous studies reported that sulfur isotopic ratios of sulfide minerals are different between on-axis and off-axis sites in the Southern Mariana Trough (Ishibashi et al. 2006; Kakegawa et al. 2008).
In this study, we conducted further detailed descriptions of mineral and chemical compositions in hydrothermal minerals from the Snail, Yamanaka, Archaean and Pika sites to evaluate the geochemical characteristics between on-axis and off-axis seafloor hydrothermal mineralizations.
2 Samples
From 2003 to 2005, mineralized samples were collected from the Southern Mariana Trough by submersible diving and shallow drilling. Sample localities are shown in Figs. 22.1, 22.2, 22.3, and 22.4.
Sampling at the Snail site was conducted during YK03-09 cruise. Sulfide crusts (sample #788-1 and #794-3) seen around the hydrothermal discharge were collected. The sample (#788-1) is a piece of hard sulfide crusts with 3–5 cm thickness, showing porous texture. Exterior surface has a thin oxidized layer (Fig. 22.5a). An inactive chimney was sampled from the Yamanaka site during TN167A cruise. The sample (#774-7) has a central conduit and has wall 2–3 cm thick (Fig. 22.5b). From the Archaean site, active and inactive chimneys and massive sulfide breccias were sampled during TN167A and YK05-09 cruises. Samples (#903-2 and #903-4) of active chimneys were obtained from orifice and body of 343 °C black smoker chimney (Fig. 22.5c). Inactive chimneys (sample #903-6) were sampled from the top of a sulfide mound accompanying shimmering of low-temperature fluids. Sample #903-7 is a large flange structure that has many spires on its surface (Fig. 22.5d). Three massive sulfide breccias (sample #903-1, #903-5 and #774-10) were collected from surface of sulfide mounds, which are considered as parts of relict chimneys (Fig. 22.5e). Mineralized samples from the Pika site were collected during YK05-09 and BMS 2004 cruises, and can be categorized in three groups: active chimney, massive sulfide breccia, and drill core. An active chimney sample was obtained from <60 °C clear smoker vent. The sample (#906-2) has tubular structure filled with later sulfides (Fig. 22.5f). Massive sulfide breccias (sample #906-1, #906-3, #906-4 and #906-5) were sampled from bottom and top of the sulfide mound. The samples are characterized by dominance of coarse-grained pyrite (Fig. 22.5g). During BMS 2004 cruise, shallow drilling by BMS (Benthic Multi-coring System, JOGMEC) was performed at the margin of the Pika mound (APM02; Fig. 22.4a). The APM02 hole (subbottom depth = 5.6 m) is entirely composed of massive sulfides beneath thin manganese oxide cover, although recovery of the core was 14 %. Four fragments were subsampled from the APM02 core (Fig. 22.5h).
3 Analytical Methods
3.1 Electron Probe X-ray Microanalysis
Chemical compositions of sulfide minerals were determined on a JEOL JCXA-733 electron probe X-ray microanalyzer at Kyushu University, using the thin sections for microscopy after dried in an oven (~80 °C) overnight and coated with evaporated carbon film. This instrument operates with a 20 kV acceleration voltage and a 10 nA specimen current.
3.2 Geochemistry of Hydrothermal Ores
Mineralized sample was subsampled (10–50 g), washed with deionized water, dried in air overnight, and ground to powder in an agate mortar. About 0.5 g of the powder sample was decomposed with 20 mL conc. HNO3 and 2 mL 31 % H2O2 on a hot plate with a temperature of about 80 °C. Soon after evaporated to dryness, the precipitates were dissolved in 10 mL 5 N HNO3. The solution was diluted to proper concentration and conditioned to 1 N HNO3. Analyses were performed using a Shimadzu AA-680 atomic absorption/flame emission spectrophotometer at Kyushu University.
3.3 Fluid Inclusion Microthermometry
Doubly polished thick sections of sphalerite, barite, anhydrite and gypsum were prepared for fluid inclusion study. Microthermometric measurements of fluid inclusions were performed under near infrared (IR) light using Olympus BX51-IR1. Heating and freezing were run using Linkam TH-600, calibrated using synthetic fluid inclusions.
3.4 Sulfur Isotope Measurement
Sulfur isotopic compositions of sulfide and barite samples were measured at the University of Tokyo using a Thermo Finnigan DELTAplus mass spectrometer. To prepare SO2 for mass spectrometry, thermal decomposition of BaSO4 with V2O5 and SiO2 described by Yanagisawa and Sakai (1983) was employed. Sulfur isotopic compositions are reported as δ34S notation relative to CDT (Canyon Diablo Troilite).
4 Results and Discussion
4.1 Mineralogy, Fluid Inclusion Microthermometry and Mineral Parageneses
Sulfide crust samples from the Snail site show moderately zoned texture from interior to exterior. The inner layer is enriched in colloform marcasite with minor amount of pyrite overgrowing barite. Small blebs of chalcopyrite are rarely seen. The intermediate layer, which occupies large part of the crust, consists of predominant sphalerite, common marcasite, barite and amorphous silica, and minor pyrite, chalcopyrite, galena and tennantite. Sphalerite contains small inclusions of chalcopyrite, galena and tennantite (Fig. 22.6a). Galena and tennantite are common in seafloor hydrothermal minerals on arc and backarc environments (Herzig et al. 2002). Marcasite and pyrite occur as blebs in sphalerite and barite. Some early barite was replaced by sulfides such as sphalerite and marcasite, and some late barite cuts sphalerite, marcasite and pyrite. Yet much of barite appears to be precipitated contemporary with sulfide mineralization. The outermost zone is composed of fine-grained barite with little sulfides. Sulfides and barite are mantled by amorphous silica.
Paragenetic sequence for mineralization at the Snail site is shown in Fig. 22.7a. Fine-grained barite is the first mineral to precipitate. At a higher temperature, small blebs of marcasite and sphalerite are associated with barite (stage I). An isotopic equilibrium temperature (cf., Sect. 22.4.4) of 224 °C was obtained for the mineral assemblage marcasite and sphalerite of the stage I. A ratio of sulfides and barite and crystallinity of sulfides increase with increasing temperature, and replacement of sphalerite by tennantite and chalcopyrite occurs (stage II). Precipitation of galena is confined to the stage II, suggesting that galena is precipitated at a higher temperature. A sphalerite-hosted fluid inclusion from stage II mineralization yielded trapping temperature of 261 °C, which is about 10 °C lower than maximum vent fluid temperature recorded in May 2003. At the waning stage, barite is precipitated in open spaces as relatively coarse crystals. These barites have fluid inclusions with trapping temperatures 188 and 200 °C. Amorphous silica fills the interstices of sulfides and barite at the last (stage III).
Inactive chimney collected from the Yamanaka site is enriched in sphalerite, marcasite and chalcopyrite. Marcasite and lesser amount of pyrite frequently form dendritic and/or colloform aggregates. Pyrite in the inner wall occasionally exhibits cubic morphology. Chalcopyrite disease (Barton and Bethke 1987) in sphalerite is common (Fig. 22.6b). Wurtzite is identified under transmitted polarized light using its anisotropy. Lining of chalcopyrite, which replaces sphalerite, is predominant along central conduit. The exterior surface has a thin layer composed of marcasite, pyrite, sphalerite and barite, which would be formed by fluid seepage through the chimney body.
Paragenetic sequence for mineralization at the Yamanaka site is shown in Fig. 22.7b. Fine-grained barite and dendritic and/or framboidal marcasite are the first mineral assemblage to precipitate, followed by precipitation of sphalerite, marcasite, pyrite and chalcopyrite (stage I). Wurtzite, which can be precipitated by rapid cooling of hydrothermal fluids as a metastable phase, would be associated with relatively early mineralization. An isotopic equilibrium temperature (cf., Sect. 22.4.4) of 306 °C was obtained for the assemblage pyrite/marcasite and sphalerite. This temperature is about 50 °C higher than a trapping temperature of sphalerite-hosted fluid inclusion (256 °C), but may be closer to the maximum temperature of mineralization at the Yamanaka site. Much of chalcopyrite in the Yamanaka sample extensively replaces sphalerite and marcasite/pyrite (stage II). Reactions for the replacement would be written as follows (Ohmoto 1996):
These reactions can take place when hydrothermal fluid is undersaturated with respect to sphalerite but saturated with respect to chalcopyrite. These conditions would be satisfied by increase in temperature of the hydrothermal fluid. Smaller amounts of marcasite, pyrite, sphalerite and barite would be precipitated at the waning stage (stage III).
Active chimneys from the base of 343 °C black smoker at the Archaean site consist of abundant pyrite and marcasite, common sphalerite and chalcopyrite, and minor barite, iss (intermediate solid solution), tennantite, jordanite, chalcocite and covellite. Intermediate solid solution is associated with sphalerite, chalcopyrite and pyrite (Fig. 22.6c). Tennantite and jordanite occur locally as tiny blebs in sphalerite. Barite occurs only in outermost part of the chimney, where colloform marcasite is predominant. The inner part has abundant pyrite and chalcopyrite, and lacks marcasite. Anhydrite-hosted fluid inclusions from the 343 °C vent orifice have trapping temperatures ranging from 276 to 349 °C. This temperature range can be explained by precipitation mechanism of anhydrite by mixing of vent fluids with seawater. Salinities of these inclusions have a wide range between 3.2 and 5.4 wt% NaCl. Inactive chimneys from the Archaean mounds contain abundant marcasite, common pyrite, sphalerite and barite, and minor tennantite and jordanite. Marcasite and pyrite occur as cryptocrystalline or colloform aggregates. Sphalerite mantles colloform marcasite, and the sphalerite is in turn mantled by jordanite (Fig. 22.6d). Much of barite occurs as late-stage infillings of conduits and interstices. Massive sulfide rubbles from the Archaean mound are predominated by cryptocrystalline pyrite and marcasite with lesser amounts of sphalerite, chalcopyrite and barite, which are relatively simple mineralogy. Pyrite and marcasite intimately coexist and seem to have replaced much of sphalerite and chalcopyrite. Tabular barite is precipitated within interstices of sulfides and even replacing sulfides (Fig. 22.6e). Chalcocite and covellite occur as secondary minerals.
Mineralization from the Archaean site has five paragenetic successions (Fig. 22.7c). Anhydrite disseminated with pyrite, sphalerite and chalcopyrite is the first mineral assemblage to precipitate from black smoker fluids (stage I). According to the maturity of the chimney, sulfide mineralization involving pyrite, marcasite, sphalerite and chalcopyrite becomes predominant (stage II). Here, iss is precipitated at a temperature higher than 340 °C. Sphalerite precipitated under such a high-temperature condition. Replacement of sphalerite and pyrite/marcasite by chalcopyrite (reactions 1 and 2) would also occur at the Archaean site. However, resulting chalcopyrite would be, in turn, replaced by pyrite/marcasite by the following reaction (Ohmoto 1996):
High-temperature acidic hydrothermal fluids undersaturated with chalcopyrite can drive this reaction. The product H2S can cause direct precipitation of pyrite/marcasite by the following reaction (Ohmoto 1996):
Much of the assemblage sphalerite + pyrite/marcasite + chalcopyrite is consequently replaced by pyrite/marcasite by the reactions 3 and 4 (stage III). At the waning stage, sphalerite (trapping temperature = 300 °C) is the predominant mineral to precipitate with accessory minerals such as tennantite and jordanite. Barite is the last mineral to precipitate under a temperature between 208 and 130 °C (salinities = 3.2–5.2 wt% NaCl).
Active chimney sampled from the Pika site consists of abundant cryptocrystalline marcasite and pyrite, common sphalerite and chalcopyrite, and rare jordanite and barite. Zonation of marcasite/pyrite, sphalerite and chalcopyrite is well developed (Fig. 22.6f). Massive sulfide breccias from the Pika mound are composed of coarse-grained euhedral pyrite so called pyritohedrons, which coalesce each other to form massive pyrite breccia (Fig. 22.6g). Cryptocrystalline texture of pyrite is rarely seen, and no sulfide phase other than pyrite is recognized. Cracks within massive sulfide breccias are locally filled with gypsum and lesser amount of anhydrite. A thin rind of Fe-oxides and sulfate is also found on their exterior. Fluid inclusions in anhydrite filling cracks of massive sulfides yielded trapping temperature ranges between 306 and 328 °C for primary inclusions and 232 and 278 °C for secondary inclusions. Trapping temperatures of primary inclusions are mostly within a range between 320 and 330 °C, which is well consistent with a maximum vent fluid temperature. The primary inclusions hosted by anhydrite yielded a wide salinity range between 3.5 and 5.4 wt% NaCl, while the secondary inclusions yielded salinities from 4.2 to 4.3 wt% NaCl. Pyrite is an only component of drill core samples recovered from the APM02 hole at the Pika site. Pyrite of these samples is characterized by cryptocrystalline texture (Fig. 22.6h), which can be recognized as formed under relatively low-temperature conditions (e.g., Ramdohr 1980). In addition, these core samples represent relatively porous texture.
Figure 22.7d shows the mineral paragenesis for the Pika mineralization. Barite, marcasite, pyrite, chalcopyrite and sphalerite (trapping temperatures = 291 and 296 °C) with accessory jordanite are the early sulfide phases (stage I). Replacement of sphalerite by the reaction 1 is common in this stage. At the main stage of mineralization, sphalerite and chalcopyrite are significantly replaced by pyrite by the reaction 3 (stage II). When the chimney composed of massive pyrite is cracked, anhydrite is precipitated to fill the cracks. Subsequently, anhydrite is hydrated by ambient seawater to form gypsum, followed by precipitation of barite at the waning stage (stage III).
4.2 Characteristics of Chemical Compositions for Selected Minerals
The FeS contents in sphalerite grains from the Southern Mariana Trough are shown in Fig. 22.8. Sphalerite from the Snail site has a narrow range of FeS contents between nil and 1.8, and 0.4 mol% on average. FeS contents in sphalerite/wurtzite from the Yamanaka site range between 0.3 and 6.9 mol%, averaging 2.5 mol%. On the other hand, sphalerite from the off-axial sites has wider ranges of FeS contents. Sphalerite in active chimneys from the Archaean site contains 2.2–22.5 mol% FeS and has average FeS content of 6.5 mol%. Sphalerite in inactive chimneys has FeS contents ranging from nil to 7.3, and 2.7 mol% on average. Sphalerite in massive sulfide breccias contains 2.0–17.3 mol% FeS and has average FeS contents of 7.5 mol%. For sphalerite from the Pika site, FeS contents have a range between 0.8 and 9.1 mol% and an average value of 4.8 mol%.
The sulfur fugacity (fS2) of hydrothermal fluids for each site was determined using the FeS content in sphalerite and a formation temperature of the sphalerite (Scott and Barnes 1971). The calculated fS2 of hydrothermal systems in the Southern Mariana Trough is low for off-axial sites and high for on-axial sites. The mineralizations from the Archaean and Pika sites yielded lower fS2, plotted near the equilibrium between pyrite and pyrrhotite. In sediment-free mid-ocean ridge systems, the pyrite-pyrrhotite buffer controls the fS2 condition (e.g., Hannington et al. 1995). The Snail site is plotted near the sulfidation equilibrium between tennantite and enargite. Compared with the Snail site, the Yamanaka site shows a slightly lower fS2, although higher than those of off-axial sites. High fS2 condition in a hydrothermal system hosted by an arc volcano can be indicative of contribution of magmatic SO2 that disproportionates and generates H2S (de Ronde et al. 2005).
Trace metal contents in pyrite/marcasite differ by locality and sample type. Pyrite/marcasite from the Snail and Yamanaka sites have relatively high Zn (~0.23 wt%) and As (~0.08 wt%) contents. Pyrite/marcasite in chimney and massive sulfide samples from the Archaean and Pika sites have lower Zn (~0.05 wt%) and As (~0.03 wt%) contents. Copper contents in pyrite/marcasite, however, make little difference by locality and sample type. Intermediate solid solution from 343 °C black smoker at the Archaean site has chemical composition close to that of stoichiometric cubanite, and is moderately zinciferous (~1.42 wt%).
4.3 Comparison of Bulk Chemical Compositions for Mineralized Samples
Bulk chemical concentrations of mineralized samples are given in Table 22.1. Mineralized samples from the Snail and Yamanaka sites are relatively rich in Zn (11.9–48.2 wt%) and poor in Fe (0.88–9.07 wt%). These results reflect the sphalerite-dominant mineralogy of the samples. Seafloor hydrothermal mineralization formed in island arc settings can be normally differentiated from those on mid-ocean ridges by major element geochemistry. On the Cu-Zn-Fe diagram (Fig. 22.9a), mineralizations recovered from the Snail and Yamanaka sites are plotted in the arc-setting field. On the other hand, mineralized samples from the Archaean and Pika sites are characterized by higher Fe concentrations (21.3–42.9 wt%), which arise from pyrite- and marcasite-rich mineral compositions. This mineral assemblage as well as bulk chemical compositions are similar to massive pyrite ore on sediment-free mid-ocean ridges (Herzig et al. 2002) (Fig. 22.9a), although is devoid of pyrrhotite. Hydrothermal fluids from the Pika site have pH of 2.9, which is somehow acid compared with the range of mid-ocean ridge fluids (Ishibashi et al. 2006; Toki et al. Chap. 45). Therefore the solubility is enhanced and temperatures of mineral precipitation decrease, compared with those of the East Pacific Rise. As a result, pyrite is the only mineral to precipitate in high-temperature condition, and mineralization becomes enriched in Fe (Fig. 22.9a). Copper is poor in most samples (<1 wt%) except for three chimney samples. The Snail and Yamanaka samples, as well as the Archaean inactive chimneys and Pika active chimney, are rich in Pb (1,167–8,755 ppm). Occurrence of galena and jordanite and Pb-bearing sphalerite can account for the enrichment of Pb in these samples. Lead, Cd and Mn moderately to strongly correlate with Zn (Fig. 22.9b, c and Table 22.1). Samples from the Snail and Yamanaka sites have higher Pb and Zn compositions than those from the Archaean and Pika sites (Fig. 22.9b). Correlation between Mn, Cd and Zn can be explained by formation of solid solution as sphalerite. But precipitation of Mn oxyhydroxide during the low-temperature mineralization would contribute to Mn geochemistry. Correlation between Pb and Zn may be attributed to the mineralogy that sphalerite contains Pb-bearing minerals as invisible inclusions. Silver correlates more strongly with Pb (Fig. 22.9d), suggesting that Ag is incorporated in galena.
4.4 Source of a Range in Sulfur Isotopic Compositions for Sulfide and Sulfate Minerals from the Southern Mariana Trough
The hydrothermal minerals from the Southern Mariana Trough show variable δ34S values, ranging from +0.8 to +8.5 ‰ (Fig. 22.10). Sulfides from the Snail sulfide crust samples have δ34S values between +6.8 and +8.5 ‰ for sphalerite and between +6.9 and +7.9 ‰ for pyrite/marcasite. These δ34S ranges are consistent with the reported values (δ34S = +7.0 − +8.7 ‰) for sulfide crust samples from the Snail site (Kakegawa et al. 2008). Inner parts of the samples have lower δ34S values than the outer parts. An equilibrium temperature of 224 °C is calculated using the sphalerite-pyrite fractionation equation of Smith et al. (1977). Sulfides from the Yamanaka inactive chimney have δ34S values between +7.1 and +7.4 ‰ for sphalerite, between +7.0 and 7.2 ‰ for chalcopyrite and +6.4 ‰ for pyrite/marcasite. These δ34S ranges are slightly higher than those (δ34S = +5.1 − +6.3 ‰) for sulfide chimney samples from the Yamanaka site (Kakegawa et al. 2008). Sulfides from the inner wall of chimney have lower δ34S values than those from the outer wall. The pyrite-sphalerite geothermometer yields 306 °C for pyrite/marcasite-sphalerite assemblage. Sulfides from the Archaean site yielded δ34S values ranging from +4.1 to +4.3 ‰ for sphalerite and from +3.6 to +6.9 ‰ for pyrite/marcasite. Sulfides from the Pika site have δ34S values between +0.8 and +3.5 ‰ for pyrite/marcasite and +1.0 ‰ for sphalerite. These δ34S ranges are slightly higher than those (δ34S = −1.8 − +1.7 ‰) for sulfide chimney samples from the Pika site (Kakegawa et al. 2008). Sulfur isotope ratios of drill core samples (δ34S = +2.8 − +3.5 ‰) are slightly higher than those of massive sulfide samples (δ34S = +1.4 − +3.0 ‰). Barites from the Southern Mariana Trough (δ34S = +20.4 − +21.6 ‰) are isotopically close to seawater sulfate, indicating that mixing of hydrothermal fluids with seawater brought about barite precipitation. The fact that δ34S value (+20.4 ‰) of the Pika barite is slightly lower than that of the ambient seawater indicates mixing of hydrothermal fluids with a small amount of seawater and subsequent oxidation of hydrothermal sulfide. Sulfides from the on-axial sites (Snail and Yamanaka) obviously have higher δ34S values than those from the off-axial site (Pika). In addition, δ34S values of sulfides from the Archaean site, which is situated between the Snail and Pika sites, are approximately intermediate between those of the Snail and Pika sites.
There can be several processes that cause isotopic fractionation and develop a wide range in δ34S values within a single hydrothermal field. It is possible that higher δ34S values obtained from the Snail and Yamanaka sulfides are attributed to the incorporation of seawater sulfate-derived sulfur without isotopic fractionation during reducing process in a seafloor environment. Sulfur occurs as sulfate in seawater with δ34S values of about +21 ‰ (Rees et al. 1978). So the incorporation of seawater sulfate-derived sulfur reduced without isotope fractionation can increase the δ34S values. However, the theoretical modeling shows that mixing of hydrothermal fluids with seawater at the seafloor cannot generate δ34S value heavier than +4.5 ‰ (Janecky and Shanks 1988). Thus, this process cannot explain the range in the δ34S values of the Snail and Yamanaka sites. Around seafloor hydrothermal sites, heating (150–200 °C) of seawater during downflow in upper oceanic crust commonly results in the formation of anhydrite (Shanks et al. 1981; Janecky and Shanks 1988). At high-temperature conditions of above 200 °C, the anhydrite (SO4 2−) is subsequently dissolved, and partially reduced to sulfide (H2S) without isotope fractionation (Shanks et al. 1981; Shanks and Seyfried 1987). Therefore, the degree of mixing of this isotopically heavy sulfur with magmatic sulfur can account for the variation of δ34S values of sulfide minerals in the four hydrothermal sites. The other possible cause of the sulfur isotopic range is the variety in the δ34S values of the host rocks under each vent site. The incorporation of sulfur into hydrothermal fluids by leaching of igneous sulfides proceeds with little isotopic fractionation, therefore the fluid H2S should have δ34S values similar to footwall rock values (Shanks et al. 1995). The δ34S values of mid-ocean ridge basalt (MORB) vary within a narrow range of +0.1 ± 0.5 ‰ (Sakai et al. 1984). In contrast, island arc magma has higher δ34S values of up to +7 ‰ due to the presence of a subduction-related seawater sulfate component in the subarc mantle source (Ueda and Sakai 1984). The δ34S values of backarc magma lie between those of MORB and island arc rocks (Alt et al. 1993). In the Southern Mariana Trough, the close proximity of arc volcanoes to the spreading center may be responsible for the axial high of the spreading center. The proximity, as well as the radial faulting pattern of the eastern backarc basin south of 13°10′N, may facilitate channeling of arc magma to the spreading center (Fryer 1995; Fryer et al. 1998). Martinez et al. (2000) proposed that the well-developed spreading system, in contrast to the rifting-stage system of the Northern Mariana Trough, channels arc magma efficiently along the backarc-spreading axis. They also suggested that the small arc seamounts in the Southern Mariana Trough may also support the derivation of the arc magmatic budget to the spreading center. Although there are no sulfur isotopic data of footwall volcanic rocks from the Snail, Yamanaka, Archaean and Pika sites, basement rocks from the four hydrothermal fields have geochemical signatures of slab-derived components (Nakamura et al., Chap. 41). Moreover, our data show that mineralizations from the on-axial sites tend to have an arc-like geochemical signatures compared with those from the off-axial sites. Therefore, at the moment, we cannot rule out the possibility that the sulfur isotope variations of sulfide minerals from the four hydrothermal sites are influenced by sulfur isotopic characteristics of volcanic rocks under each vent site.
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Acknowledgments
We wish to thank SHINKAI 6500 and ROV ROPOS team members, crews of the R/V YOKOSUKA and R/V Thomas G. Thompson, and onboard scientists for their skillful support during the YK03-09, YK05-09 and TN167A cruises. We also thank crews of the R/V Hakurei-Maru No.2 during the BMS2004 cruise for their cooperation. Profs. Hitoshi Chiba and Shunichi Nakai are thanked for their constructive comments that helped improve the manuscript. This study was supported by the Ministry of Education, Culture, Sports, Science and Technology (MEXT) of Japan through a Special Coordination Fund “Archaean Park Project” and a Grant-in-Aid for Scientific Research on Innovative Areas “TAIGA project”. This study was also financially supported by JSPS and NSF, respectively.
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Ikehata, K., Suzuki, R., Shimada, K., Ishibashi, Ji., Urabe, T. (2015). Mineralogical and Geochemical Characteristics of Hydrothermal Minerals Collected from Hydrothermal Vent Fields in the Southern Mariana Spreading Center. In: Ishibashi, Ji., Okino, K., Sunamura, M. (eds) Subseafloor Biosphere Linked to Hydrothermal Systems. Springer, Tokyo. https://doi.org/10.1007/978-4-431-54865-2_22
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