数据报告:IODP expedition 366孔隙水微量元素(V、Mo、Rb、Cs、U、Ba、Li)组成

G. Wheat, T. Fournier, C. Paul, C. Menzies, R. Price, J. Ryan, Olivier Sissman
{"title":"数据报告:IODP expedition 366孔隙水微量元素(V、Mo、Rb、Cs、U、Ba、Li)组成","authors":"G. Wheat, T. Fournier, C. Paul, C. Menzies, R. Price, J. Ryan, Olivier Sissman","doi":"10.14379/IODP.PROC.366.201.2018","DOIUrl":null,"url":null,"abstract":"International Ocean Discovery Program (IODP) Expedition 366 focused, in part, on the study of geochemical cycling, matrix alteration and transport, and deep biosphere processes in the Mariana subduction zone. This research was accomplished by sampling the summit and flank regions of three active serpentinite mud volcanoes in the Mariana forearc: Yinazao (Blue Moon), Fantangisña (Celestial), and Asùt Tesoro (Big Blue) Seamounts. These mud volcanoes represent a transect with increasing distance from the trench. Because these mud volcanoes discharge fluids and materials from the subduction channel, they provide a means to characterize thermal, geochemical, and pressure conditions within the seismogenic zone. Previous coring on Ocean Drilling Program (ODP) Legs 125 and 195 at two other serpentinite mud volcanoes (Conical and South Chamorro Seamounts, respectively) and piston, gravity, and push cores from several other Mariana serpentinite mud volcanoes add to this transect of deep-sourced material that is discharged at the seafloor. Pore waters were squeezed from cored serpentinite materials to determine the composition of deep-sourced fluid from the subduction channel and to assess the character, extent, and effect of diagenetic reactions and mixing with seawater on the flanks of three serpentinite seamounts (Yinazao, Fantangisña, and Asùt Tesoro). In addition, two water-sampling temperature probe (WSTP) fluid samples were collected in two of the cased boreholes, each with at least 30 m of screened casing that allowed formation fluids to discharge into the borehole. Here we report shore-based Li, Rb, Cs, Ba, V, Mo, and U measurements of pore waters and one of the WSTP samples. The alkali metals were analyzed to constrain the temperature of reaction in the subduction channel. The other elements were analyzed to assess potential biogenic and diagenetic reactions as the serpentinite material weathers and exchanges with bottom seawater via diffusion. Results were generally consistent with earlier coring and drilling operations, resulting in systematic changes in the composition of the deep-sourced fluid with distance from the trench. Introduction One goal of International Ocean Discovery Program (IODP) Expedition 366 was to elucidate geochemical cycling within the subduction channel of the Mariana forearc system (see the Expedition 366 summary chapter [Fryer et al., 2018b]). Expedition 366 successfully cored the flank and summit regions of three Mariana forearc serpentinite mud volcanoes that are located along a transect with increasing distance from the trench and by inference with depth to the subducted Pacific plate (Figure F1). Previous scientific drilling during Ocean Drilling Program (ODP) Legs 125 and 195 at two other Mariana serpentinite mud volcanoes, Conical and South Chamorro Seamounts, respectively, as well as piston, gravity, and push cores from several other Mariana serpentinite mud volcanoes add additional geochemical data to this transect of active serpentinite mud volcanoes in the Mariana forearc (Fryer, Pearce, Stokking, et al., 1990; Salisbury, Shinohara, Richter, et al., 2002; Mottl et al., 2004; Hulme et al., 2010). One of the expedition’s primary objectives was to determine the composition of deep-sourced fluid to characterize thermal, geochemical, and pressure conditions within the subduction channel by sampling the summit region where newly deposited material is currently being delivered. A second primary objective was to assess the character, extent, and effect of diagenetic reactions and mixing with seawater on the flanks of three serpentinite mud volcanoes, thus C.G. Wheat et al. Data report: pore water trace element compositions providing constraints for the extent of continued serpentinite reactions and potential microbial metabolic activity. To meet these two objectives, 149 whole-round samples were collected for pore water extraction. Extracted pore waters were analyzed shipboard, aliquoted into a range of containers, and preserved for shore-based analyses (see the Expedition 366 summary chapter [Fryer et al., 2018b]). In addition, two fluid samples were collected using the water-sampling temperature probe (WSTP) within two cased boreholes, each with screened casing that allows formation fluids to flow into the borehole while retaining the mud matrix (e.g., ODP Hole 1200C; Wheat et al., 2008). Although pore waters were analyzed for many dissolved ions and gases at sea, shipboard instrumentation limits some critical analyses. This paper remedies this limitation by presenting results from analyses of trace elements, particularly Rb and Cs. These two elements constrained the temperature of the deep-sourced fluid, given their similar chemistries but different mobilization characteristics (e.g., Hulme et al., 2010). Lithium concentration data, another alkali metal, also is presented because many samples have concentrations that were below the detection limit afforded by the shipboard instrument. Other trace elements (V, Mo, Ba, and U) were measured and are presented to provide a gauge for potential reactions and diagenetic pathways on the flanks of the seamount. Methods Coring with the half-length advanced piston corer (HLAPC) was the primary method used to acquire material during Expedition 366 (see the Expedition 366 methods chapter [Fryer et al., 2018a]). We also recovered material with extended core barrel (XCB) and rotary core barrel (RCB) coring. Recovered materials included serpentinite mudflows with clasts from the flanks of each of three edifices and pelagic sediment: Sites U1491 (Yinazao [Blue Moon] Seamount), U1493, U1494, U1495 (Asùt Tesoro [Big Blue] Seamount), and U1498 (Fantangisña [Celestial] Seamount) (Figure F1). The serpentinite mudflow matrix differed in color with depth and, although distinctly disturbed by flow-in during HLAPC and XCB coring, discrete horizons of clast content and matrix constituents remained in place. Serpentinite material also was recovered from the summit regions of each of the three cored mud volcanoes: Sites U1492 (Yinazao Seamount), U1496 (Asùt Tesoro Seamount), and U1497 (Fantangisña Seamount). Serpentinite material and sediment for pore water analysis were immediately taken from the catwalk and placed in a refrigerator to cool samples to near (2°–5°C) the in situ temperature (see the Expedition 366 methods chapter [Fryer et al., 2018a]). Serpentinite and sediment samples were then extracted from the core liner in a nitrogen-filled glove bag, scraped to remove the outer contaminated rind, and placed into a titanium squeezer. The squeezer was removed from the glove bag and inserted into the press. Pore waters were expelled, filtered, aliquoted, preserved, and stored for a range of shore-based analyses. A total of 149 pore water samples and 2 WSTP samples were collected during Expedition 366. Unfortunately, not all of the whole-round samples provided sufficient fluids for shore-based analyses for each solute or isotope. Only the WSTP sample from Hole U1496C is included in this data set. Analyses presented herein were conducted using the identical inductively coupled plasma–mass spectrometry (ICP-MS) and inductively coupled plasma–optical emission spectrometry (ICPOES) methods that Mottl et al. (2004) and Hulme et al. (2010) used, thus ensuring continuity among data sets. Trace elements (V, Mo, Rb, Cs, U, and Ba) were analyzed on 103 samples using an ICP-MS with a 1:50 dilution in 3% ultra-pure nitric acid and standard machine settings (Table T1). Standards were matrix matched with bottom seawater from the eastern flank of the Juan de Fuca Ridge (Wheat et al., 2010). This seawater and a blank were analyzed about every 8 to 10 samples to account for machine drift. The average concentration of this bottom seawater and the standard deviation are listed in Table T1. The lack of sensitivity in the Li measurements at sea led us to analyze 127 samples on an ICP-OES with a 1:25 dilution in 3% ultrapure nitric acid utilizing standard axial machine settings (Table T1). Concurrent with this measurement, we also measured B, Ba, Mn, Fe, Si, and Sr, and we measured Ca, Mg, K, Na, and S on a separate aliquot with a 1:100 dilution. These analyses were conducted to confirm that shipboard results were consistent with results that were generated during prior work (e.g., Mottl et al., 2004; Hulme et al., 2010). As expected, results from these shore-based analyses and shipboard results agree within analytical precision. Duplicate shorebased results are not presented because the entire data set was not analyzed and the IODP database already includes measured values. Deep-sourced fluid compositions for the three seamounts that were drilled during Expedition 366 were calculated based on pore water data from the summit boreholes for which the fluid composition reaches an asymptotic composition with depth. Such profiles are consistent with deep-sourced fluids that upwell faster than the surrounding serpentinite matrix (e.g., Fryer, Pearce, Stokking, et al., 1999; Mottl et al., 2003, 2004; Hulme et al., 2010). Concentrations calculated for the deep-sourced fluid for Yinazao Seamount were generally based on the average concentration of pore waters from Figure F1. Locations of IODP Expedition 366 Sites U1491–U1498 and Site 1200 on South Chamorro Seamount superimposed on a regional bathymetric map. (From the Expedition 366 summary chapter [Fryer et al., 2018b].) -8000 -6000 -4000 -2000 0 -90 00 -9 00 0 -000 -9 00 0 -9 00 0 -8 00 0 -8 00 0 -000 -8 00 0 00","PeriodicalId":20641,"journal":{"name":"Proceedings of the International Ocean Discovery Program","volume":"49 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2018-08-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"10","resultStr":"{\"title\":\"Data report: IODP Expeditiom 366 pore water trace element (V, Mo, Rb, Cs, U, Ba, and Li) compositions\",\"authors\":\"G. Wheat, T. Fournier, C. Paul, C. Menzies, R. Price, J. Ryan, Olivier Sissman\",\"doi\":\"10.14379/IODP.PROC.366.201.2018\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"International Ocean Discovery Program (IODP) Expedition 366 focused, in part, on the study of geochemical cycling, matrix alteration and transport, and deep biosphere processes in the Mariana subduction zone. This research was accomplished by sampling the summit and flank regions of three active serpentinite mud volcanoes in the Mariana forearc: Yinazao (Blue Moon), Fantangisña (Celestial), and Asùt Tesoro (Big Blue) Seamounts. These mud volcanoes represent a transect with increasing distance from the trench. Because these mud volcanoes discharge fluids and materials from the subduction channel, they provide a means to characterize thermal, geochemical, and pressure conditions within the seismogenic zone. Previous coring on Ocean Drilling Program (ODP) Legs 125 and 195 at two other serpentinite mud volcanoes (Conical and South Chamorro Seamounts, respectively) and piston, gravity, and push cores from several other Mariana serpentinite mud volcanoes add to this transect of deep-sourced material that is discharged at the seafloor. Pore waters were squeezed from cored serpentinite materials to determine the composition of deep-sourced fluid from the subduction channel and to assess the character, extent, and effect of diagenetic reactions and mixing with seawater on the flanks of three serpentinite seamounts (Yinazao, Fantangisña, and Asùt Tesoro). In addition, two water-sampling temperature probe (WSTP) fluid samples were collected in two of the cased boreholes, each with at least 30 m of screened casing that allowed formation fluids to discharge into the borehole. Here we report shore-based Li, Rb, Cs, Ba, V, Mo, and U measurements of pore waters and one of the WSTP samples. The alkali metals were analyzed to constrain the temperature of reaction in the subduction channel. The other elements were analyzed to assess potential biogenic and diagenetic reactions as the serpentinite material weathers and exchanges with bottom seawater via diffusion. Results were generally consistent with earlier coring and drilling operations, resulting in systematic changes in the composition of the deep-sourced fluid with distance from the trench. Introduction One goal of International Ocean Discovery Program (IODP) Expedition 366 was to elucidate geochemical cycling within the subduction channel of the Mariana forearc system (see the Expedition 366 summary chapter [Fryer et al., 2018b]). Expedition 366 successfully cored the flank and summit regions of three Mariana forearc serpentinite mud volcanoes that are located along a transect with increasing distance from the trench and by inference with depth to the subducted Pacific plate (Figure F1). Previous scientific drilling during Ocean Drilling Program (ODP) Legs 125 and 195 at two other Mariana serpentinite mud volcanoes, Conical and South Chamorro Seamounts, respectively, as well as piston, gravity, and push cores from several other Mariana serpentinite mud volcanoes add additional geochemical data to this transect of active serpentinite mud volcanoes in the Mariana forearc (Fryer, Pearce, Stokking, et al., 1990; Salisbury, Shinohara, Richter, et al., 2002; Mottl et al., 2004; Hulme et al., 2010). One of the expedition’s primary objectives was to determine the composition of deep-sourced fluid to characterize thermal, geochemical, and pressure conditions within the subduction channel by sampling the summit region where newly deposited material is currently being delivered. A second primary objective was to assess the character, extent, and effect of diagenetic reactions and mixing with seawater on the flanks of three serpentinite mud volcanoes, thus C.G. Wheat et al. Data report: pore water trace element compositions providing constraints for the extent of continued serpentinite reactions and potential microbial metabolic activity. To meet these two objectives, 149 whole-round samples were collected for pore water extraction. Extracted pore waters were analyzed shipboard, aliquoted into a range of containers, and preserved for shore-based analyses (see the Expedition 366 summary chapter [Fryer et al., 2018b]). In addition, two fluid samples were collected using the water-sampling temperature probe (WSTP) within two cased boreholes, each with screened casing that allows formation fluids to flow into the borehole while retaining the mud matrix (e.g., ODP Hole 1200C; Wheat et al., 2008). Although pore waters were analyzed for many dissolved ions and gases at sea, shipboard instrumentation limits some critical analyses. This paper remedies this limitation by presenting results from analyses of trace elements, particularly Rb and Cs. These two elements constrained the temperature of the deep-sourced fluid, given their similar chemistries but different mobilization characteristics (e.g., Hulme et al., 2010). Lithium concentration data, another alkali metal, also is presented because many samples have concentrations that were below the detection limit afforded by the shipboard instrument. Other trace elements (V, Mo, Ba, and U) were measured and are presented to provide a gauge for potential reactions and diagenetic pathways on the flanks of the seamount. Methods Coring with the half-length advanced piston corer (HLAPC) was the primary method used to acquire material during Expedition 366 (see the Expedition 366 methods chapter [Fryer et al., 2018a]). We also recovered material with extended core barrel (XCB) and rotary core barrel (RCB) coring. Recovered materials included serpentinite mudflows with clasts from the flanks of each of three edifices and pelagic sediment: Sites U1491 (Yinazao [Blue Moon] Seamount), U1493, U1494, U1495 (Asùt Tesoro [Big Blue] Seamount), and U1498 (Fantangisña [Celestial] Seamount) (Figure F1). The serpentinite mudflow matrix differed in color with depth and, although distinctly disturbed by flow-in during HLAPC and XCB coring, discrete horizons of clast content and matrix constituents remained in place. Serpentinite material also was recovered from the summit regions of each of the three cored mud volcanoes: Sites U1492 (Yinazao Seamount), U1496 (Asùt Tesoro Seamount), and U1497 (Fantangisña Seamount). Serpentinite material and sediment for pore water analysis were immediately taken from the catwalk and placed in a refrigerator to cool samples to near (2°–5°C) the in situ temperature (see the Expedition 366 methods chapter [Fryer et al., 2018a]). Serpentinite and sediment samples were then extracted from the core liner in a nitrogen-filled glove bag, scraped to remove the outer contaminated rind, and placed into a titanium squeezer. The squeezer was removed from the glove bag and inserted into the press. Pore waters were expelled, filtered, aliquoted, preserved, and stored for a range of shore-based analyses. A total of 149 pore water samples and 2 WSTP samples were collected during Expedition 366. Unfortunately, not all of the whole-round samples provided sufficient fluids for shore-based analyses for each solute or isotope. Only the WSTP sample from Hole U1496C is included in this data set. Analyses presented herein were conducted using the identical inductively coupled plasma–mass spectrometry (ICP-MS) and inductively coupled plasma–optical emission spectrometry (ICPOES) methods that Mottl et al. (2004) and Hulme et al. (2010) used, thus ensuring continuity among data sets. Trace elements (V, Mo, Rb, Cs, U, and Ba) were analyzed on 103 samples using an ICP-MS with a 1:50 dilution in 3% ultra-pure nitric acid and standard machine settings (Table T1). Standards were matrix matched with bottom seawater from the eastern flank of the Juan de Fuca Ridge (Wheat et al., 2010). This seawater and a blank were analyzed about every 8 to 10 samples to account for machine drift. The average concentration of this bottom seawater and the standard deviation are listed in Table T1. The lack of sensitivity in the Li measurements at sea led us to analyze 127 samples on an ICP-OES with a 1:25 dilution in 3% ultrapure nitric acid utilizing standard axial machine settings (Table T1). Concurrent with this measurement, we also measured B, Ba, Mn, Fe, Si, and Sr, and we measured Ca, Mg, K, Na, and S on a separate aliquot with a 1:100 dilution. These analyses were conducted to confirm that shipboard results were consistent with results that were generated during prior work (e.g., Mottl et al., 2004; Hulme et al., 2010). As expected, results from these shore-based analyses and shipboard results agree within analytical precision. Duplicate shorebased results are not presented because the entire data set was not analyzed and the IODP database already includes measured values. Deep-sourced fluid compositions for the three seamounts that were drilled during Expedition 366 were calculated based on pore water data from the summit boreholes for which the fluid composition reaches an asymptotic composition with depth. Such profiles are consistent with deep-sourced fluids that upwell faster than the surrounding serpentinite matrix (e.g., Fryer, Pearce, Stokking, et al., 1999; Mottl et al., 2003, 2004; Hulme et al., 2010). Concentrations calculated for the deep-sourced fluid for Yinazao Seamount were generally based on the average concentration of pore waters from Figure F1. Locations of IODP Expedition 366 Sites U1491–U1498 and Site 1200 on South Chamorro Seamount superimposed on a regional bathymetric map. (From the Expedition 366 summary chapter [Fryer et al., 2018b].) -8000 -6000 -4000 -2000 0 -90 00 -9 00 0 -000 -9 00 0 -9 00 0 -8 00 0 -8 00 0 -000 -8 00 0 00\",\"PeriodicalId\":20641,\"journal\":{\"name\":\"Proceedings of the International Ocean Discovery Program\",\"volume\":\"49 1\",\"pages\":\"\"},\"PeriodicalIF\":0.0000,\"publicationDate\":\"2018-08-13\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"10\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Proceedings of the International Ocean Discovery Program\",\"FirstCategoryId\":\"1085\",\"ListUrlMain\":\"https://doi.org/10.14379/IODP.PROC.366.201.2018\",\"RegionNum\":0,\"RegionCategory\":null,\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"\",\"JCRName\":\"\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Proceedings of the International Ocean Discovery Program","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.14379/IODP.PROC.366.201.2018","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 10

摘要

国际海洋发现计划(IODP) 366远征队的部分重点是研究马里亚纳俯冲带的地球化学循环、基质蚀变和运输以及深层生物圈过程。本研究通过对马里亚纳前弧的三个活火山——Yinazao (Blue Moon)、Fantangisña (Celestial)和Asùt Tesoro (Big Blue)海山的山顶和侧翼区域进行采样来完成。这些泥火山代表了一个离海沟越来越远的样带。由于这些泥火山从俯冲通道排出流体和物质,它们提供了一种表征发震区内热、地球化学和压力条件的方法。海洋钻探计划(ODP)第125号和第195号腿对另外两座蛇纹岩泥火山(分别为圆锥海山和南查莫罗海山)和其他几个马里亚纳蛇纹岩泥火山的活塞、重力和推动岩心进行了取样,增加了海底排放的深源物质的样带。从取心蛇纹岩物质中挤压孔隙水,以确定俯冲通道深部流体的组成,并评估三个蛇纹岩海山(Yinazao、Fantangisña和Asùt Tesoro)侧翼成岩反应和海水混合的特征、程度和影响。此外,在两个套管井眼中收集了两个水采样温度探头(WSTP)流体样本,每个井眼至少有30米的屏蔽套管,允许地层流体排放到井眼中。在这里,我们报告了孔隙水和WSTP样品之一的岸基Li, Rb, Cs, Ba, V, Mo和U的测量。分析了碱金属对俯冲通道反应温度的约束作用。对其他元素进行了分析,以评估蛇纹岩物质在与海底海水扩散和交换过程中可能发生的生物成因和成岩反应。结果与早期的取心和钻井作业基本一致,导致深部流体成分随着距离海沟的距离而发生系统性变化。国际海洋发现计划(IODP)远征366的一个目标是阐明马里亚纳前弧系统俯冲通道内的地球化学循环(见远征366总结章[Fryer et al., 2018b])。366探险队成功地取芯了三座马里亚纳弧前蛇纹岩泥火山的侧翼和峰顶区域,这些火山位于离海沟越来越远的样带上,由此推断,随着深度的增加,它们与俯冲的太平洋板块之间的距离也在增加(图F1)。海洋钻探计划(ODP)第125和195号阶段的科学钻探,分别在另外两个马里亚纳蛇纹岩泥火山,圆锥海山和南查莫罗海山进行,以及来自其他几个马里亚纳蛇纹岩泥火山的活塞、重力和推动岩心,为马里亚纳前弧的活跃蛇纹岩泥火山样带提供了额外的地球化学数据(Fryer, Pearce, Stokking等,1990;索尔兹伯里,筱原,Richter等,2002;Mottl et al., 2004;Hulme et al., 2010)。此次考察的主要目标之一是确定深层流体的组成,以表征俯冲通道内的热、地球化学和压力条件,方法是对目前正在运送新沉积物质的峰顶区域进行采样。第二个主要目标是评估三个蛇纹岩泥火山两侧成岩反应和海水混合的特征、程度和影响,因此C.G. Wheat等人。数据报告:孔隙水微量元素组成限制了蛇纹石持续反应的程度和潜在的微生物代谢活性。为了实现这两个目标,我们采集了149个完整的样品进行孔隙水提取。提取的孔隙水在船上进行分析,将其放入一系列容器中,并保存下来用于岸上分析(见Expedition 366总结章[Fryer et al., 2018b])。此外,在两个套管井眼内使用水样温度探头(WSTP)收集了两个流体样本,每个套管都有屏蔽套管,允许地层流体流入井眼,同时保留泥浆基质(例如,ODP井眼1200C;Wheat et al., 2008)。虽然在海上对孔隙水中的许多溶解离子和气体进行了分析,但船上的仪器限制了一些关键的分析。本文通过介绍微量元素,特别是Rb和Cs的分析结果来弥补这一局限性。由于这两种元素的化学性质相似,但其动员特性不同,因此限制了深层流体的温度(例如,Hulme等人,2010年)。 另一种碱金属锂的浓度数据也被提出,因为许多样品的浓度低于船上仪器提供的检测极限。其他微量元素(V、Mo、Ba和U)的测量为海底山两侧的潜在反应和成岩途径提供了一种衡量标准。半长先进活塞盖取心(HLAPC)是远征366期间获取材料的主要方法(参见远征366方法章节[Fryer等人,2018a])。我们还使用扩展取心筒(XCB)和旋转取心筒(RCB)取心来回收材料。回收的材料包括蛇纹岩泥流和来自三个建筑物两侧的碎屑,以及上层沉积物:U1491 (Yinazao [Blue Moon]海山)、U1493、U1494、U1495 (Asùt Tesoro [Big Blue]海山)和U1498 (Fantangisña [Celestial]海山)(图F1)。蛇纹岩泥流基质的颜色随深度不同而不同,尽管在HLAPC和XCB取心过程中明显受到流入的干扰,但碎屑含量和基质成分的离散层位仍然存在。在三个岩心泥火山:U1492 (Yinazao海山)、U1496 (Asùt Tesoro海山)和U1497 (Fantangisña海山)的山顶区域也发现了蛇纹岩物质。用于孔隙水分析的蛇纹岩材料和沉积物立即从t台上取出,并放置在冰箱中,将样品冷却到接近(2°-5°C)的原位温度(参见Expedition 366方法章节[Fryer et al., 2018a])。然后将蛇纹石和沉积物样品从岩心衬里中取出,放入一个充满氮气的手套袋中,刮去外部污染的外壳,并放入钛挤压器中。挤压器从手套袋中取出并插入压力机。孔隙水被排出、过滤、提取、保存和储存,用于一系列基于海岸的分析。366次考察共采集孔隙水样品149份,WSTP样品2份。不幸的是,并非所有的完整样本都能提供足够的流体,用于岸上对每种溶质或同位素的分析。本数据集中仅包含来自U1496C孔的WSTP样本。本文的分析使用了Mottl等人(2004)和Hulme等人(2010)使用的相同的电感耦合等离子体质谱(ICP-MS)和电感耦合等离子光学发射光谱(ICPOES)方法,从而确保了数据集之间的连续性。在3%的超纯硝酸和标准机器设置中,使用ICP-MS以1:50稀释对103个样品进行微量元素(V、Mo、Rb、Cs、U和Ba)分析(表T1)。标准与来自Juan de Fuca Ridge东部侧翼的海底海水进行基质匹配(Wheat et al., 2010)。这些海水和空白大约每8到10个样本进行一次分析,以解释机器漂移。该海底海水的平均浓度及标准差列于表T1。由于海上Li测量缺乏灵敏度,我们利用标准轴向机设置,在3%超纯硝酸中以1:25稀释的ICP-OES分析了127个样品(表T1)。与此同时,我们还测量了B、Ba、Mn、Fe、Si和Sr,并测量了Ca、Mg、K、Na和S,稀释比例为1:100。进行这些分析是为了确认船上的结果与之前工作中产生的结果一致(例如,Mottl等人,2004;Hulme et al., 2010)。正如预期的那样,岸上分析结果和船上分析结果在分析精度范围内是一致的。由于没有对整个数据集进行分析,并且IODP数据库已经包含了测量值,因此没有提供重复的基于海岸的结果。考察366期间钻探的三个海山的深层流体成分是根据顶部钻孔的孔隙水数据计算的,其中流体成分随深度渐近。这种剖面与深部流体的上涌速度比周围的蛇纹岩基体快一致(例如,Fryer, Pearce, Stokking等,1999;Mottl et al., 2003, 2004;Hulme et al., 2010)。依那藻海山深层流体的浓度计算一般基于图F1中孔隙水的平均浓度。南查莫罗海山IODP考察队366站点U1491-U1498和站点1200位置叠加在区域等深地图上。(来自探险366总结章[Fryer et al., 2018b].) -8000 -6000 -4000 -2000 0 - 9000 - 900 000 - 900 000 -800 000 -800 000 -800 000 -800 000 000
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Data report: IODP Expeditiom 366 pore water trace element (V, Mo, Rb, Cs, U, Ba, and Li) compositions
International Ocean Discovery Program (IODP) Expedition 366 focused, in part, on the study of geochemical cycling, matrix alteration and transport, and deep biosphere processes in the Mariana subduction zone. This research was accomplished by sampling the summit and flank regions of three active serpentinite mud volcanoes in the Mariana forearc: Yinazao (Blue Moon), Fantangisña (Celestial), and Asùt Tesoro (Big Blue) Seamounts. These mud volcanoes represent a transect with increasing distance from the trench. Because these mud volcanoes discharge fluids and materials from the subduction channel, they provide a means to characterize thermal, geochemical, and pressure conditions within the seismogenic zone. Previous coring on Ocean Drilling Program (ODP) Legs 125 and 195 at two other serpentinite mud volcanoes (Conical and South Chamorro Seamounts, respectively) and piston, gravity, and push cores from several other Mariana serpentinite mud volcanoes add to this transect of deep-sourced material that is discharged at the seafloor. Pore waters were squeezed from cored serpentinite materials to determine the composition of deep-sourced fluid from the subduction channel and to assess the character, extent, and effect of diagenetic reactions and mixing with seawater on the flanks of three serpentinite seamounts (Yinazao, Fantangisña, and Asùt Tesoro). In addition, two water-sampling temperature probe (WSTP) fluid samples were collected in two of the cased boreholes, each with at least 30 m of screened casing that allowed formation fluids to discharge into the borehole. Here we report shore-based Li, Rb, Cs, Ba, V, Mo, and U measurements of pore waters and one of the WSTP samples. The alkali metals were analyzed to constrain the temperature of reaction in the subduction channel. The other elements were analyzed to assess potential biogenic and diagenetic reactions as the serpentinite material weathers and exchanges with bottom seawater via diffusion. Results were generally consistent with earlier coring and drilling operations, resulting in systematic changes in the composition of the deep-sourced fluid with distance from the trench. Introduction One goal of International Ocean Discovery Program (IODP) Expedition 366 was to elucidate geochemical cycling within the subduction channel of the Mariana forearc system (see the Expedition 366 summary chapter [Fryer et al., 2018b]). Expedition 366 successfully cored the flank and summit regions of three Mariana forearc serpentinite mud volcanoes that are located along a transect with increasing distance from the trench and by inference with depth to the subducted Pacific plate (Figure F1). Previous scientific drilling during Ocean Drilling Program (ODP) Legs 125 and 195 at two other Mariana serpentinite mud volcanoes, Conical and South Chamorro Seamounts, respectively, as well as piston, gravity, and push cores from several other Mariana serpentinite mud volcanoes add additional geochemical data to this transect of active serpentinite mud volcanoes in the Mariana forearc (Fryer, Pearce, Stokking, et al., 1990; Salisbury, Shinohara, Richter, et al., 2002; Mottl et al., 2004; Hulme et al., 2010). One of the expedition’s primary objectives was to determine the composition of deep-sourced fluid to characterize thermal, geochemical, and pressure conditions within the subduction channel by sampling the summit region where newly deposited material is currently being delivered. A second primary objective was to assess the character, extent, and effect of diagenetic reactions and mixing with seawater on the flanks of three serpentinite mud volcanoes, thus C.G. Wheat et al. Data report: pore water trace element compositions providing constraints for the extent of continued serpentinite reactions and potential microbial metabolic activity. To meet these two objectives, 149 whole-round samples were collected for pore water extraction. Extracted pore waters were analyzed shipboard, aliquoted into a range of containers, and preserved for shore-based analyses (see the Expedition 366 summary chapter [Fryer et al., 2018b]). In addition, two fluid samples were collected using the water-sampling temperature probe (WSTP) within two cased boreholes, each with screened casing that allows formation fluids to flow into the borehole while retaining the mud matrix (e.g., ODP Hole 1200C; Wheat et al., 2008). Although pore waters were analyzed for many dissolved ions and gases at sea, shipboard instrumentation limits some critical analyses. This paper remedies this limitation by presenting results from analyses of trace elements, particularly Rb and Cs. These two elements constrained the temperature of the deep-sourced fluid, given their similar chemistries but different mobilization characteristics (e.g., Hulme et al., 2010). Lithium concentration data, another alkali metal, also is presented because many samples have concentrations that were below the detection limit afforded by the shipboard instrument. Other trace elements (V, Mo, Ba, and U) were measured and are presented to provide a gauge for potential reactions and diagenetic pathways on the flanks of the seamount. Methods Coring with the half-length advanced piston corer (HLAPC) was the primary method used to acquire material during Expedition 366 (see the Expedition 366 methods chapter [Fryer et al., 2018a]). We also recovered material with extended core barrel (XCB) and rotary core barrel (RCB) coring. Recovered materials included serpentinite mudflows with clasts from the flanks of each of three edifices and pelagic sediment: Sites U1491 (Yinazao [Blue Moon] Seamount), U1493, U1494, U1495 (Asùt Tesoro [Big Blue] Seamount), and U1498 (Fantangisña [Celestial] Seamount) (Figure F1). The serpentinite mudflow matrix differed in color with depth and, although distinctly disturbed by flow-in during HLAPC and XCB coring, discrete horizons of clast content and matrix constituents remained in place. Serpentinite material also was recovered from the summit regions of each of the three cored mud volcanoes: Sites U1492 (Yinazao Seamount), U1496 (Asùt Tesoro Seamount), and U1497 (Fantangisña Seamount). Serpentinite material and sediment for pore water analysis were immediately taken from the catwalk and placed in a refrigerator to cool samples to near (2°–5°C) the in situ temperature (see the Expedition 366 methods chapter [Fryer et al., 2018a]). Serpentinite and sediment samples were then extracted from the core liner in a nitrogen-filled glove bag, scraped to remove the outer contaminated rind, and placed into a titanium squeezer. The squeezer was removed from the glove bag and inserted into the press. Pore waters were expelled, filtered, aliquoted, preserved, and stored for a range of shore-based analyses. A total of 149 pore water samples and 2 WSTP samples were collected during Expedition 366. Unfortunately, not all of the whole-round samples provided sufficient fluids for shore-based analyses for each solute or isotope. Only the WSTP sample from Hole U1496C is included in this data set. Analyses presented herein were conducted using the identical inductively coupled plasma–mass spectrometry (ICP-MS) and inductively coupled plasma–optical emission spectrometry (ICPOES) methods that Mottl et al. (2004) and Hulme et al. (2010) used, thus ensuring continuity among data sets. Trace elements (V, Mo, Rb, Cs, U, and Ba) were analyzed on 103 samples using an ICP-MS with a 1:50 dilution in 3% ultra-pure nitric acid and standard machine settings (Table T1). Standards were matrix matched with bottom seawater from the eastern flank of the Juan de Fuca Ridge (Wheat et al., 2010). This seawater and a blank were analyzed about every 8 to 10 samples to account for machine drift. The average concentration of this bottom seawater and the standard deviation are listed in Table T1. The lack of sensitivity in the Li measurements at sea led us to analyze 127 samples on an ICP-OES with a 1:25 dilution in 3% ultrapure nitric acid utilizing standard axial machine settings (Table T1). Concurrent with this measurement, we also measured B, Ba, Mn, Fe, Si, and Sr, and we measured Ca, Mg, K, Na, and S on a separate aliquot with a 1:100 dilution. These analyses were conducted to confirm that shipboard results were consistent with results that were generated during prior work (e.g., Mottl et al., 2004; Hulme et al., 2010). As expected, results from these shore-based analyses and shipboard results agree within analytical precision. Duplicate shorebased results are not presented because the entire data set was not analyzed and the IODP database already includes measured values. Deep-sourced fluid compositions for the three seamounts that were drilled during Expedition 366 were calculated based on pore water data from the summit boreholes for which the fluid composition reaches an asymptotic composition with depth. Such profiles are consistent with deep-sourced fluids that upwell faster than the surrounding serpentinite matrix (e.g., Fryer, Pearce, Stokking, et al., 1999; Mottl et al., 2003, 2004; Hulme et al., 2010). Concentrations calculated for the deep-sourced fluid for Yinazao Seamount were generally based on the average concentration of pore waters from Figure F1. Locations of IODP Expedition 366 Sites U1491–U1498 and Site 1200 on South Chamorro Seamount superimposed on a regional bathymetric map. (From the Expedition 366 summary chapter [Fryer et al., 2018b].) -8000 -6000 -4000 -2000 0 -90 00 -9 00 0 -000 -9 00 0 -9 00 0 -8 00 0 -8 00 0 -000 -8 00 0 00
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