1. Introduction
The seepage of fluids containing methane associated with gas hydrate dissociation and free gas release is widely observed on the seafloor at a global scale [1,2,3,4,5,6,7]. At cold seeps, more than 80% of the methane is oxidized by pore-water sulfate in the sulfate–methane transition zone (SMTZ) in the sediment; this process is well known as the sulfate-driven anerobic oxidation of methane (AOM) is mediated by a consortium of methanotrophic archaea and sulfate-reducing bacteria (Equation (1) CH4 + SO42−→HS− + HCO32− + H2O) [8,9,10,11]. Furthermore, bio-irrigation related to the activity of benthic organisms is a key control on the turnover rates of reduced and oxidized carbon and sulfur components between anoxic sediment and oxygenated bottom water [12].
In addition, the organic matter (CH2O) within sediments can be oxidized by pore-water sulfate via microbial sulfate reduction: the so-called organiclastic sulfate reduction (OSR, Equation (2): 2(CH2O) + SO42−→H2S + 2HCO3−) [13,14,15,16,17]. These processes can induce the precipitation of authigenic carbonate concretions, gypsum (CaSO4·2H2O), and pyrite (FeS2) within sediment [13,14,15,16].
Methane seepage activity varies temporo-spatially, leading to significant changes in sedimentary redox conditions [18,19], diagenetic conditions within seepage areas, and the composition of local microbial communities [20,21,22,23,24,25,26,27,28]. Even though gypsum is a classical evaporite mineral that is undersaturated in seawater, calcium sulfate minerals (e.g., gypsum and bassanite) and pyrite have been found in modern and ancient methane-seep environments (e.g., southwest African Margin, South China Sea (SCS)) [15,17,29,30,31,32,33,34,35,36]. Pyrite usually formed in sulfidic environments, which indicates hydrogen sulfide formed by AOM, and the precipitation of authigenic gypsum at cold seep is caused by an enrichment in sulfate derived from pyrite re-oxidation after cold seepage ceased [12,17,29,37]. Therefore, the occurrence of gypsum indicates the intermittent characteristics of cold seeps.
The δ13C composition of foraminifera is a common proxy for reconstructing changes in paleoceanographic and paleo-climate conditions, because foraminifera are sensitive to these changes and ubiquitous in marine settings [38,39]. In cold-seep areas, owing to the prokaryote food source for foraminifera and cemented authigenic carbonate or the incorporation of dissolved inorganic carbon (DIC) with negative d13C values into the shells, the foraminifera δ13C values can be depleted extremely in 13C in the stratigraphic record, with more negative δ13C values (−4‰ to −25‰) than those found in typical marine settings (0 < δ13C < 1.5‰) [38,39,40,41,42,43,44,45,46,47,48,49]. Hence, it can be interpreted as an indicator of methane seepages over geological time [40,41,50,51,52,53,54,55,56,57,58,59,60,61,62]. Furthermore, the abundances and diversities of the foraminiferal assemblages at cold seeps are generally lower than those of typical marine settings (non-seep areas) [42,43,63,64,65,66]. Several studies investigated the correlation between benthic foraminiferal communities (composition, abundance, diversity and dominant species) and hydrocarbon emissions [43,59,67,68,69,70]. Therefore, it is necessary to combine multiple indices to better describe the active characteristics and histories of cold seeps.
In recent years, many cold seeps have been discovered in the northern South China Sea, but active cold seeps have been found only in the Beikang basin in the southern South China Sea [71]. Therefore, besides the Beikang Basin, are cold seeps developed elsewhere, such as the Nansha Trough in the southern South China Sea? Additionally, what about the characteristics and histories of cold seeps? Here we describe the stable carbon isotopic composition of planktonic foraminifera Globigerinoides ruber and detailed microscopic observations of authigenic gypsum and pyrite in gas hydrate areas of the Nansha Trough in the southern SCS, with the aim of reconstructing methane flux at past cold seeps and their dynamic characteristics.
2. Materials and Methods 2.1. Study Area
The study area lies in the Nansha Trough at the southeastern margin of the Nansha Islands (Figure 1). The Nansha Trough is the largest trough developed along a SW–NE fault depression in the southern SCS. It has a sedimentary thickness of up to 2000 m, and lies on the edge of the NW–SE Nansha compressional belt. It contains NE–SW normal faults, thrust faults and NW–SE secondary strike-slip faults [72]. Since the early Miocene, the trough has undergone complex processes of collisional, tensional and compressional deformation, with hydrocarbon gas formation and migration via leakage forces and transport channels [73], forming and storing rich oil and gas resources. The tectonic background of the trough is also conducive to the movement of biogenic gas to shallow layers, which provide a favorable site for the accumulation and storage of natural gas hydrate. In addition, bottom-simulating reflectors were recognized in the southern SCS, indicating gas hydrate accumulation [74].
2.2. Sampling and Analyses Sedimentary core 2PC, studied here, was retrieved from the Nansha trough at a water depth of 2796 m by the RV Haiyang-4 of the Guangzhou Marine Geological Survey, Guangzhou, China. The sediment core was 808 cm long, and samples were taken at 2 cm intervals, weighed and freeze-dried. Dry samples were weighed and wet-sieved with a mesh size of 63 µm to separate carbonate, gypsum and pyrite crystals from the sediment. The remaining sediment was dried at 60 °C for carbon and oxygen isotopic analyses of planktonic foraminifera. The gypsum and pyrite aggregates from the coarse fraction were identified using a high-power stereoscopic microscope and a Hitachi TM3030 Scanning Electron Microscope (SEM) in Energy Dispersive Spectrum (EDS) mode at the Guangzhou Marine Geological Survey, Guangzhou, China.
Stable isotopic compositions of planktonic foraminifera Globigerinoides ruber were determined after picking up a 63–250 μm fraction from the sediment and cleaning it by a standard method [75]. The first step cleans the specimens mechanically by rinsing in distilled water and reagent grade methanol repeatedly, and by washing ultrasonically to remove adhering detrital material [75]. The second step removes the organic matter by soaking the specimens in 15% hydrogen peroxide for 15 min, followed by rinsing with methanol [75]. Globigerinoides ruber were broken using a metal probe and then treated with anhydrous phosphoric acid at 73 °C. The carbon and oxygen isotopic compositions of the foraminifera were determined using a Finnigan 253 mass spectrometer equipped with an automatic carbonate preparation device (Kiel III) at SunYat-Sen University, Guangzhou, China. Isotopic compositions were reported as an average of two analyses and normalized to Vienna Pee Dee Belemnite (VPDB), using International atomic energy agency (IAEA) reference materials 18 and 19, with standard deviations of ±0.07‰ for δ18O and ±0.04‰ for δ13C. In addition, we did not analyze the benthic foraminifera due to the lack of benthic foraminifera in the sediment core 2PC.
3. Results 3.1. Morphological Characteristics of Authigenic Pyrite and Gypsum Aggregates
Authigenic gypsum crystals and pyrite are two major authigenic minerals in sediment from core 2PC, and are found at depth intervals of 199–200, 221–222, 249–250, and 299–300 cm below seafloor (bsf) (Figure 2). There are also small amounts of quartz, plagioclase, K-feldspar, and so on. The morphology of authigenic gypsum and pyrite is shown in Figure 2 and Figure 3. Pyrite may be present alone, but gypsum can only occur with pyrite in the cold seeps [33]. Gypsum is dark-yellow in color, and translucent to opaque. The dark-gray, black, or brown gypsum aggregates partly or completely enveloped pyrite (Figure 2), which is similar to that developed on the slopes of the southwest Atlantic [12]. Gypsum crystals are about 1–2 mm in size, are euhedral, and variable in shape with more or less prismatic or lenticular forms that are generally isolated and rarely twinned (Figure 2A–D). The gypsums are transparent, dark-yellow or dull, with etched surfaces and commonly contain inclusions of sedimentary particles. Pyrite occurs as aggregates of framboids on the surfaces of planktonic foraminifera (Figure 2E), and as micrometer-sized octahedral crystals that form tubular structures of about 10 mm long (Figure 2F).
SEM observations revealed that gypsum crystals are most commonly rhombic and trapezoidal in shape (Figure 3A–E), with some microcrystals occurring in radiating gypsum clusters. The individual crystals in such clusters show a range of morphologies (Figure 3A–C). Euhedral trapezoidal morphologies have enlarged {111} and {110} faces (Figure 3D). Clusters of gypsum crystals are commonly euhedral, with no obvious paragenetic sequence (Figure 3E).
Scanning Electron Microscopy (SEM) and Energy Dispersive Spectrum (EDS) analyses indicate that gypsum microcrystals adhere to the surface of planktonic foraminifera (Figure 3G,H). Pyrite aggregates have a black appearance, and occur in the shape of straight and irregular tubes of ~40 μm length, or in chambers of foraminifera tests (Figure 3F).
3.2. Stable Isotopic Compositions of Planktonic Foraminifera
Stable isotopic compositions (indicated by δ18O and δ13C values) of planktonic foraminifera Globigerinoides ruber are plotted against depth in Figure 4. δ13C values vary within a range from −4.46‰ to +1.77‰, with most values being lower than those of the typical marine environment in the late Quaternary SCS [60,61,62]. The δ18O values of planktonic foraminifera generally show a trend opposite to the δ13C values (Figure 4), with values from −2.91‰ to +0.27‰. Negative δ13C values correspond to positive δ18O values along the profile (Figure 4).
4. Discussion 4.1. Paleo-Methane Release in the Nansha Trough
Extreme 13C depletion of planktonic and benthic foraminifera, caused by overgrowths of AOM-derived authigenic carbonate or the assimilation of methane-derived DIC produced by AOM in the sediment core, can be used as an indicator of methane emission events (MEEs) in the geological records [40,41,51,52,53,54,55,56,57,76]. Two major MEEs (MEE-1 and MEE-2) are evident in core 2PC, as indicated by the anomalous δ13C values that are well beyond the normal marine range (Figure 4 and Figure 5). MEE-1, in the range of 150–250 cm bsf is characterized by a remarkable δ13C excursion (Figure 4), while MEE-2 is characterized by negative δ13C values at 350–370 cm bsf (Figure 4). Planktonic foraminifera negative δ13C values correspond to the negative δ13C of sediment DIC at the same depth, indicating that planktonic foraminifera shells inherit the negative δ13C values of authigenic carbonate cementation. In addition, the positive δ18O excursions of planktonic foraminifera may be affected by several reasons, such as gas hydrate decomposition [52], higher δ18O value of the sediment pore water where the carbonate rocks formed than that of the surface seawater [44], or the low temperature of the bottom seawater [77]. Overall, our δ13C isotopic records of planktonic foraminifera in core 2PC reveal that the two major MEEs may have distinct characteristics in terms of timing, duration and intensity.
4.2. Authigenic Gypsum and Pyrite as Indicators of the Paleo-SMTZ
Although seawater is largely undersaturated with respect to gypsum, it is the most common source of Ca2+ and SO42−, which combine to form gypsum when saturation is reached [79]. In modern marine sediment environments with a lack of evaporation of pore fluids, the only way to achieve gypsum saturation is to add Ca2+ and/or SO42− ions to pore water [79], with several possible sources of Ca2+ and SO42− ions being available [17]. The most straightforward source is brine fluid arising from the dissolution of evaporite deposits, as in the Eastern Mediterranean [80] and Gulf of Mexico [81]. Another is the alteration of volcanic material, which increases the concentration of Ca2+ in pore solutions to supersaturation levels.
In a methane-rich, cold-seep environment, biogeochemical processes that control the cycling of reduced and oxidized carbon and sulfur components can significantly increase pore-water SO42− concentrations to enable the precipitation and dissolution of authigenic minerals in anoxic sediment. Examples include the oxidation of sedimentary sulfide minerals [82], the anerobic re-oxidation of authigenic sulfides [83], and the disproportionation reactions of sulfide oxidation intermediates [84,85] in interstitial waters, as observed in the porewaters of a giant cold-water coral mounds on the Pen Duick Escarpment, Gulf of Cadiz [30,85]. The dissolution of calcium carbonate minerals (calcite or aragonite) precipitated by AOM or the oxidation of sulfide can also increase Ca2+ concentrations in pore-water [15,17,30,86].
The morphology of gypsum crystals in core 2PC indicates an authigenic origin. Differences in the crystal morphology of authigenic gypsum may be controlled by precipitation rates or chemical variations in the pore-water environment [86,87,88]. In SEM and stereoscopic images, all gypsum crystals appear euhedral, with sizes of a few millimeters and smooth surfaces (Figure 2 and Figure 3), suggesting in-situ formation in a burial setting, similar to authigenic gypsum in the northern South China Sea and the southwest African Margin [12,17]. Furthermore, gypsum encloses pyrite (Figure 2), indicating its formation was related to the oxidation or re-oxidation of sedimentary sulfide minerals. Therefore, the presence of gypsum in the sediment core indicates the intermittency of cold seeps and the dynamic characteristics of methane activity.
Sedimentary pyrite is generated from dissolved sulfide ions reacting with reactive detrital iron minerals [89], as in the northern Gulf of Mexico continental slope [32]. The formation of tubular pyrite is related to hydrogen sulfide diffusion in sediments, bioturbation, or tubeworms in the sediment [16,17,90]. Framboids including tube pyrite in core 2PC were generated from sulfide ions in the pore-water by rapid nucleation and crystal growth via the pyrite precursors mackinawite (FeS) or greigite (Fe3S4) [16,89,90,91,92,93,94].
Euhedral gypsum crystals are usually produced directly from supersaturated solutions in hypersulfidic and anoxic conditions within the sediment [7]. Authigenic gypsum is abundant in three intervals (221–222, 249–250 and 299–300 cm bsf), each of which is also a pyrite enrichment zone (Figure 4). Furthermore, the enrichment zones of authigenic gypsum and pyrite correspond to extreme 13C depletions of planktonic foraminifera, indicating that gypsum is only formed after pyrite is formed, and the establishment of more oxidizing conditions, probably caused by waning seepage [17]. However, no gypsum or pyrite occurs at 350–370 cm bsf, although the negative δ13C value of planktonic foraminifera is beyond the normal marine range. The occurrence of authigenic gypsum in the sediment core thus indicates that the past methane-releasing events ceased.
5. Conclusions In this study, authigenic minerals (gypsum and pyrite) and stable carbon and oxygen isotopes of planktonic foraminifera from cold-seep sediments of the Nansha Trough were used to identify dynamic methane-release events. Two extremely negative δ13C values of planktonic foraminifera, lower than those of the typical marine environment, were found in sediment core 2PC. Such anomalous δ13C values are caused by the assimilation of methane-derived DIC produced by AOM with a very low δ13C signature, which can be interpreted as representing historic MEEs. Authigenic gypsum and pyrite occur at three levels in core 2PC, and are the products of biogeochemical redox reactions. Their profile positions correspond to those of the extremely negative δ13C values of planktonic foraminifera, indicating that the decreased methane-release flux can cause the SMTZ to migrate downward. MEE-1, characterized by extreme 13C depletion relative to MEE-2, is likely the stronger and longer-lasting MEE. Overall, our results provide evidence of dynamic methane emissions, with the depth of the SMTZ and methane-emission fluxes varying in the past.
Enlarge this image.Figure 1. Maps showing the locations of the study area (red rectangle) and sediment core 2PC (yellow dot) in the southern South China Sea (SCS).
Enlarge this image.Figure 2. Microscopic observations of authigenic gypsum and pyrite. (A) Gypsum with prismatic, transparent and dull forms (249-250 cm depth); (B) prismatic gypsum crystals enclosing pyrite (249-250 cm depth); (C) prismatic, transparent and dull gypsum (299-300 cm); (D) prismatic gypsum crystals enclosing pyrite (299-300 cm); (E) A planktonic foraminifer coated with framboidal pyrite (299-300 cm); (F) tubular pyrite (221-222 cm).
Enlarge this image.Figure 3. Scanning electron microscopy (SEM) observations and Energy Dispersive Spectrum (EDS) analysis of gypsum and pyrite aggregates from core 2PC. (A) Clusters of bladed gypsum microcrystals; (B) clusters of bladed gypsum microcrystals with framboidal pyrite; (C) clusters of bladed gypsum microcrystals; (D) gypsum crystal with trapezoidal shape and with clay minerals on its surface; (E) euhedral gypsum crystals; (F) tubular pyritized structure with secondary gypsum on its surface; (G) gypsum crystal growth on planktonic foraminifera (G. ruber); (H) EDS spectra of the gypsum indicated in (G).
![View Image - Figure 4. Stable isotopic compositions of planktonic foraminifera Globigerinoides ruber in core 2PC. Two major methane emission events (MEEs) were found. The black rectangles indicate three depth intervals of authigenic gypsum crystals and pyrite (199-200, 221-222, 249-250 and 299-300 cm bsf). The gray rectangle indicates the range of planktonic foraminifera 13C of typical marine settings [60,61,62].](https://media.proquest.com/media/hms/THUM/8/brj2G?_a=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%3D%3D&_s=68g6G%2BCUf7qYKf%2Ft7lcI9caAw9A%3D "View Image - Figure 4. Stable isotopic compositions of planktonic foraminifera Globigerinoides ruber in core 2PC. Two major methane emission events (MEEs) were found. The black rectangles indicate three depth intervals of authigenic gypsum crystals and pyrite (199-200, 221-222, 249-250 and 299-300 cm bsf). The gray rectangle indicates the range of planktonic foraminifera 13C of typical marine settings [60,61,62].")
Enlarge this image.Figure 4. Stable isotopic compositions of planktonic foraminifera Globigerinoides ruber in core 2PC. Two major methane emission events (MEEs) were found. The black rectangles indicate three depth intervals of authigenic gypsum crystals and pyrite (199-200, 221-222, 249-250 and 299-300 cm bsf). The gray rectangle indicates the range of planktonic foraminifera 13C of typical marine settings [60,61,62].
![View Image - Figure 5.δ13C vs. δ18O diagram for planktonic foraminifera Globigerinoides ruber and sediment inorganic carbon. The white circles represent the stable isotopic records of planktonic foraminifera from core 2PC; black circles represent the stable isotopic records of sediment inorganic carbon from the core [78]. The gray rectangle indicates the range of planktonic foraminifera Globigerinoides ruber δ13C values of typical marine settings of the South China Sea [60,62].](https://media.proquest.com/media/hms/THUM/10/brj2G?_a=ChgyMDI1MDgwNjAyMTc1NDg0NDo0MDg2MDESBzEzODMzMjMaCk9ORV9TRUFSQ0giDjIxNi43My4yMTYuMTgwKgcyMDMyMzU3MgoyMzgzNTI0MzQ1OgtJbmxpbmVJbWFnZUIBMFIGT25saW5lWgNJTEliBFRIVU1qCjIwMjAvMDEvMDFyCjIwMjAvMTIvMzF6AIIBIFAtMTAwMDA4NC0yMDEzOTUtU1RBRkYtbnVsbC1udWxskgEGT25saW5lygFnTW96aWxsYS81LjAgQXBwbGVXZWJLaXQvNTM3LjM2IChLSFRNTCwgbGlrZSBHZWNrbzsgY29tcGF0aWJsZTsgQ2xhdWRlQm90LzEuMDsgK2NsYXVkZWJvdEBhbnRocm9waWMuY29tKdIBElNjaG9sYXJseSBKb3VybmFsc5oCB1ByZVBhaWSqAhtPUzpFTVMtRnVsbFRleHQtZ2V0RnVsbFRleHTKAg9BcnRpY2xlfEZlYXR1cmXiAgDyAgD6AgFZggMDV2ViigMcQ0lEOjIwMjUwODA2MDIxNzU0ODQ0OjU4ODMyNQ%3D%3D&_s=%2B%2F1X%2F48OU7Qi%2FvwCDlJKJ4fHDWg%3D "View Image - Figure 5.δ13C vs. δ18O diagram for planktonic foraminifera Globigerinoides ruber and sediment inorganic carbon. The white circles represent the stable isotopic records of planktonic foraminifera from core 2PC; black circles represent the stable isotopic records of sediment inorganic carbon from the core [78]. The gray rectangle indicates the range of planktonic foraminifera Globigerinoides ruber δ13C values of typical marine settings of the South China Sea [60,62].")
Enlarge this image.Figure 5.δ13C vs. δ18O diagram for planktonic foraminifera Globigerinoides ruber and sediment inorganic carbon. The white circles represent the stable isotopic records of planktonic foraminifera from core 2PC; black circles represent the stable isotopic records of sediment inorganic carbon from the core [78]. The gray rectangle indicates the range of planktonic foraminifera Globigerinoides ruber δ13C values of typical marine settings of the South China Sea [60,62].
Author Contributions
Conceptualization: P.D. and N.L.; methodology: Y.Z., X.S., F.C., J.Z. and N.L.; formal analysis: Y.Z.; investigation: P.D. and N.L.; resources: Y.Z. and N.L.; data curation: Y.Z., P.D. and N.L.; writing-original draft preparation: Y.Z. and P.D.; writing-review and editing: P.D. and N.L.; project administration: P.D. and N.L.; funding acquisition: Y.Z., P.D. and N.L. All authors have read and agreed to the published version of the manuscript.
Funding
This study was partially supported by the National Key R&D Program of China (2018YFC0310004), the National Natural Science Foundation of China (41506065, 41706053, 41676046, 41976061), the Qingdao National Laboratory for Marine Science and Technology (QNLM2016ORP0204), the Guangdong Basic and Applied Basic Research Foundation (2019A1515011809) and the Key Special Project for Introduced Talents Team of Southern Marine Science and Engineering Guangdong Laboratory (Guangzhou) (GML2019ZD0104).
Acknowledgments
We thank the crew of the research vessel Haiyang-04 for their support at sea.
Conflicts of Interest
The authors declare no conflict of interest.
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Yang Zhou1, Pengfei Di2,3,4,5,*, Niu Li2,3,4,5, Fang Chen1, Xin Su6 and Jinpeng Zhang1
1MNR Key Laboratory of Marine Mineral Resources, Guangzhou Marine Geological Survey, Ministry of Natural Resources, Guangzhou, Guangdong 510075, China
2Key Laboratory of Ocean and Marginal Sea Geology, South China Sea Institute of Oceanology, Chinese Academy of Sciences, Guangzhou 510301, China
3Laboratory for Marine Mineral Resources, Qingdao National Laboratory for Marine Science and Technology, Qingdao 266061, China
4Innovation Academy of South China Sea Ecology and Environmental Engineering, Chinese Academy of Sciences, Guangzhou 510301, China
5Southern Marine Science and Engineering Guangdong Laboratory (Guangzhou), Guangzhou 511481, China
6School of Ocean Sciences, China University of Geosciences, Beijing 100083, China
*Author to whom correspondence should be addressed.
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; Niu, Li; Chen, Fang; Su, Xin; Zhang, Jinpeng