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doi:10.2204/iodp.pr.333.2011 Principal resultsSite C0018The primary goals of drilling IODP Site C0018 were to establish a well-dated Quaternary mass-movement event stratigraphy and to sample the distal part of an exceptionally thick MTD for analyzing its rheological behavior to constrain sliding dynamics and tsunamigenic potential (Fig. F3). Identification of MTD intervals in cores relied on a combination of observations:
Operations
After recovering transponders by ROV, the Chikyu left Hole C0002G at 0300 h on 10 December 2010. After 8 nmi of transit with an average speed of 4 kt, the Chikyu arrived at the first transponder location for Site C0018 at 0500 h. Deployment of four transponders and calibration finished at 2045 h and we began preparation for HPCS/EPCS/ESCS coring. The 11 Core recovery was excellent for piston coring with HPCS to 153.85 m drilling depth below seafloor (DSF) (Core 333-C0018A-17H), but core liner collapse or expansion in the core barrel caused problems for several cores (Cores 333-C0018A-9H and 16H were damaged). After experiencing repeated incomplete penetration and reaching the estimated MTD bottom, the coring system was shifted to EPCS at 190.65 m DSF (Core 333-C0018A-24T). EPCS recovery was variable, ranging from 90.7% to 0% with average recovery of 47.2%, as attempts to adjust the penetration of the EPCS cutting shoe ahead of the drill bit met with mixed success. We switched to ESCS after the seventh core. ESCS core recovery was surprisingly better than expected with good recovery ranging 70.8% to 114.9% with average recovery of 87.35%. Both EPCS and ESCS were used below the MTD (EPCS from 190.65 m DSF and ESCS from 257.15 m DSF), and core quality assessment from X-ray computed tomography (CT) scans showed no major difference between EPCS and ESCS cores. Both systems formed fractured biscuits 2–4 cm thick. However, the ESCS cores appear to contain more slurry. Once split, degradation between EPCS and ESCS is obvious, as the thickness of shear zones between biscuits and core liner increases. With ESCS cores, it would be very difficult to identify small MTDs, as some were present in the formation below 257.15 m DSF. Some cores, including HPCS, were also strongly affected by gas expansion, resulting in voids and bubbly slurry intervals. OverviewSlope sediments cored in Hole C0018A are divided into two lithologic subunits. Lithologic Subunit IA is primarily composed of hemipelagic mud (or silty clay) with interbedded volcanic ash layers and is affected by MTDs (Fig. F4). Lithologic Subunit IB is a sandy turbidite sequence. Two thick ash layers were correlated on the basis of superficial appearance with onland tephra deposits (Azuki and Pink) that originated from Kyushu volcanoes (Hayashida et al., 1996). The Pink ash layer, dated on land as 0.9–1.05 Ma, lies at 183.8–190.65 m CSF, close the base of Subunit IA and the base of the thick MTD. The Azuki ash layer, dated on land as 850.000–900.000 y, is found at 125.65–126.45 m CSF, <1 m above the top of the thick MTD. These correlative ages were used to constrain magnetostratigraphy and are compatible with preliminary micropaleontological data. Six intervals with evidence for MTDs are observed within Subunit IA and numbered from top to bottom for convenience (Fig. F4). The upper boundary/contact is well defined for MTDs 1, 2, and 6 and is marked by a turbidite for two of them (MTDs 2 and 6) (Fig. F5). MTD 1 extends over 2.9 m of chaotic and convolute bedding in Core 333-C0018A-1H. MTD 2 comprises in its lower part several intervals of coherent bedding limited by probable shear zones. The lowermost one defines the base of the MTD 2 interval (Fig. F6). MTD 3 comprises an interval with visual evidence for remobilization near its top, and examination of CT scan and structural data lead to considering this interval as part of a thicker MTD zone. MTD 4 is a relatively thin interval (50 cm) associated with a fluidized ash layer (Fig. F7). MTD 5 extends over cores that were also disturbed by the coring process. A zone of remobilization is identified based on visual evidence and CT scan in Core 333-C0018A-9H, although this core was damaged during extraction from the core barrel. Evidence for a shear zone with a sharp lower boundary on CT scan images defines the base of MTD 5; however, it is yet unclear whether this MTD interval corresponds to a single event deposit. MTD 6 is a 61.36 m interval between 127.55 and 188.57 m CSF and corresponds to the main MTD body identified in the seismic data. As already noted, a turbidite deposit is found immediately above its upper boundary. Chaotic and convolute bedding (Fig. F8) and mixing of ash with hemipelagite deposits are observed in the cores, but other intervals remain coherently bedded. Several shear zones are identified from CT scans in the lower part of MTD 6, but none could be positively identified as the basal surface. The base of the thick MTD was thus defined at the top of the Pink ash layer. Important findings are a correlation of MTD occurrence with a change in sedimentation from turbidite to hemipelagite dominated and the presence of a thick ash layer at or near the base of the thick MTD. Whereas the presence of a thick ash layer at, or near, the lithologic boundary is likely coincidental, the peculiar stratigraphic context of the thick MTD suggests that sediment properties, and their variations, have a major influence on MTD occurrence and size. LithologyHole C0018A was entirely drilled in a slope basin pile/stratigraphic succession. Slope deposits overlying the accretionary wedge were defined as lithologic Unit I in previous expedition reports. In Hole C0018A, a marked difference was observed in cores between a dominantly hemipelagic section bearing ash layers, volcaniclastic sands, occasional siliclastic turbidites and intercalated MTDs forming Subunit IA (above 190.65 m CSF), and a sequence of sandy turbidites forming Subunit IB and interpreted as a sand-rich slope basin (Fig. F9). These subunits correlate with seismic Units 1a and 1b of Kimura et al. (2011). Within Subunit IA, the interval between 24.04 and 57.51 m CSF contains more abundant silty and sandy turbidites than intervals above and below. Three facies (IAi, IAii, and IAiii) are thus defined within Subunit IA. Turbidites in Facies IAii are dominantly of volcaniclastic origin. Conversely, samples with relatively higher plagioclase content, lower quartz content, and higher clay content in Facies IAii reflect an altered ash component (Fig. F10). Sequences of thin (~5 cm), silty to very fine sand turbidites are also found above ash layers in the lower part of Facies IAiii. Sands in Subunit IB have a mixed composition with quartz, plagioclase, and abundant lithic fragments of both metamorphic and volcanic origin, and thus are not considered to be volcaniclastic sands. An increase in quartz content and in the variability of mineral composition from Subunits IA to IB is observed in the X-ray diffraction (XRD) data (Fig. F10). Below 190.65 m CSF there is also a marked decrease in the relative abundance of nannofossils, diatoms, and spicules. Calcite content from bulk powder XRD, calcium content from X-ray fluorescence (XRF) (Fig. F11), and carbonate content from coulometric analysis are consistently higher in Subunit IA than in Subunit IB and tend to increase uphole within Subunit IA. This may be interpreted as a consequence of uplift above the carbonate compensation depth (Strasser et al., 2009) Two remarkably coarse-grained ash layers occur within Unit I and are attributed to cataclysmic eruptions in Kyushu, known from widespread tephra deposits on land. A normally coarse (sand-sized) ash 80 cm thick is found at 125.65–126.45 m CSF and interpreted as the Azuki event, dated on land as 850.000–900.000 y (Yoshikawa and Mitamura, 1999) (Fig. F7). A dark sand-sized to fine ash layer, which was fluidized upon coring, is found at 183.8–190.65 m CSF. Deposits from this event are characterized by abundant plate-shaped volcanic glass particles interpreted as bubble wall shards. Our provisional correlation is with the Pink event, dated on land as 0.99–1.05 Ma (Yoshikawa and Mitamura, 1999) (Fig. F7). The Subunit IA/IB boundary lies below this ash layer. Structural geologyStructural features of Site C0018 mainly record gravity-driven deformation and mass-movement processes. The main structural features from visual core description at this site are subhorizontal and southeast-dipping beds and northward- and southward-dipping normal faults, outside MTD intervals in the upper part of the borehole (0–127.26 m CSF); scattered bedding dips, fault zones, and flow structures within the thick MTD (127.55–188.57 m CSF); and subhorizontal beds and fissility below the thick MTD (188.62–313.655 m CSF) (Figs. F12, F13). A remarkable overturned fold was also observed within MTD 2 at 41.2 m CSF (Fig. F14). CT scans may provide additional evidence for shearing. Lines with very high CT values (3000 or more) were identified as early diagenetic pyrite, which may constitute a marker of ductile deformation. Furthermore, small faults and thin shear bands (<3 mm) associated with MTDs appear generally denser on CT scan images (Fig. F15), although still in the usual range for high-porosity sediment (<1500). Several intervals with pyrite mineralizations organized as lineations and bearing low-angle planar discontinuities with associated increased CT values are tentatively interpreted as shear zones (e.g., Fig. F7). BiostratigraphyPreliminary biostratigraphic determination for Site C0018 was based on examination of calcareous nannofossils. All core catcher samples and additional samples from sections were examined. Several nannofossil events were recognized with mostly good preservation. Although some reworked specimens were identified in the examined intervals, most specimens can be considered in situ. The result shows no significant time gap in Hole C0018A. The lowest core catcher at 313.61 m CSF indicates an age younger than 1.67 Ma. Ages derived from nannofossil events suggest a slower sedimentation rate (~6 cm/k.y.) in the interval of 0–25.525 m CSF corresponding to Facies IAi and a higher apparent sedimentation rate (~23 cm/k.y.) in the interval of 25.53–313.61 m CSF. This interval includes most MTDs within Subunit IA as well as Subunit IB, which is composed of sandy turbidites. PaleomagnetismShipboard paleomagnetic studies for Site C0018 were performed with remanent magnetization and magnetic susceptibility measurements of discrete samples. Recovered sediments showed considerable variation in magnetic properties and demagnetization behavior. The natural remanent magnetization (NRM) intensities span more than two orders of magnitude, and variations in magnetic susceptibility are consistent with the variations in NRM intensity. Remagnetization imparted by the coring process is commonly encountered and is characterized by NRM inclinations that are strongly biased toward vertical (mostly toward +90°) in a majority of cores. Alternating-field (AF) demagnetization to 30 mT effectively removed this drilling-induced remagnetization, as observed by a significant decrease in intensity and a shift of inclination toward shallower or negative values for intervals with normal or reversed polarity, respectively. Magnetostratigraphy is determined based on the inclination data demagnetized at 30 mT. The most diagnostic feature in the paleomagnetic polarity is a change from normal to reversed polarity within Core 333-C0018A-14H, which corresponds to the Brunhes/Matuyama Chron boundary (0.78 Ma). According to tephra chronological data, the base of a normal chron below the thick MTD horizon is correlated to the base of Jaramillo Subchron (1.07 Ma). Cores recovered with HPCS generally show a clustered distribution in declination within each core, but the declinations in the MTD intervals are scattered. This supports irregular rotation of sediments in MTDs. Physical propertiesFrom the surface to ~200 m CSF, bulk density generally increases and porosity decreases downhole, accompanied by increasing penetration and shear strength, thermal conductivity, and resistivity (Fig. F16). Porosity and resistivity are generally correlated and, arguably, MTD intervals display an increased compaction gradient compared with the average porosity-depth trend, and slight reversals (porosity increasing with depth) are observed near the base of MTDs 2, 3, 5, and 6. For the latter case (MTD 6), this could be in part related to the lithologic change between Subunits IA and IB. Shear strength displays more scatter within MTD intervals. Within the thick MTD, all physical property values (porosity, thermal conductivity, strength, and resistivity) show greater scatter than above or below. A drop in shear strength below the thick MTD at ~190 m CSF may at least in part be an artifact related to the change of coring system from HPCS to EPCS, and then ESCS. Below 200 m CSF, physical properties show no distinct trend. Inorganic geochemistryThe main geochemical objectives at this site were to document the variations in chemical composition of the interstitial water. Whole-round lengths ranged from 20 to 31.5 cm, and interstitial water volumes per centimeter of core ranged from 1.95 to 2.15 mL/cm between 0 and 130.5 m CSF (Fig. F17). Because of the consolidated nature of the formation in the deeper portion of this site and the coring techniques used, some of the deeper cores were quite disturbed. Sulfate concentration, calcium concentration, and alkalinity point to a sharp methane-sulfate reaction zone at ~15 m CSF. Below this level, we could use the sulfate concentration to identify and quantify contamination. Chlorinity increases rapidly in the upper ~30 m of Hole C0018A and then gradually increases with depth (Fig. F18). The gradual increase in chlorinity in Hole C0018A may reflect ash alteration, which consumes water. The distribution of major and minor cations documents extensive alteration of volcanogenic sediments as well (Fig. F19). The thick MTD interval is associated with lower phosphate concentration. This feature is not explained. Organic geochemistryMethane is the predominant hydrocarbon component in most cores and ranges between 0 and 19,339 ppmv (Fig. F20). Ethane is either below detection or present in low concentrations (i.e., <2 ppmv). No heavier hydrocarbon gases were detected. All C1/C2 ratios are >4000, suggesting that methane is biogenic and organic matter is immature. Calcium carbonate (CaCO3) contents average at 12.5 wt% and vary in a wide range (0.2~25.4 wt%) (Fig. F21). Total organic carbon (TOC), total nitrogen (TN), and total sulfur (TS) contents are low in the majority of cores, averaging 0.58 ± 0.16, 0.07 ± 0.02, and 0.21 ± 0.19 wt%, respectively. Parameters including CaCO3, TOC, TN, and TS contents all show larger variations in the upper ~87 m CSF and become less variable in deeper sediments. The atomic ratios of TOC to TN (TOC/TNat) fall in the range of ~3.5–15, suggesting organic matter is mostly derived from marine sources but also contains terrestrial material in some horizons. Core-seismic integrationAt Site C0018, the base of the thick MTD (MTD 6) appears very reflective in profiles from 3-D seismic data and of negative polarity. This could be related to a step increase of porosity observed at the base of the thick MTD (Fig. F16). It is unclear whether the change of physical properties observed at this level is the consequence of deformation within the MTD or of a change of lithology at the transition between lithologic Subunits IA and IB, or both. Seismic onlap surfaces above MTD 6 define the base of several suspected MTDs in seismic data. These correlate with intervals in cores with evidence for remobilization (MTDs 2, 4, and 5) (Fig. F22). The layered sequence below the thick MTD corresponds to lithologic Subunit IB, which is composed of turbidites, but these reflectors cannot be interpreted as individual events in the turbidite sequence. Downhole temperature measurementsDuring HPCS operations, downhole temperature was measured with the advanced piston corer temperature tool (APCT-3) at ~30 m intervals. Starting from 35.15 m DSF, six data points were obtained to 190.65 mbsf, but the deepest measurements at 161.65 m DSF and 190.65 mbsf may be unreliable. Other data follow a nearly linear increase in temperature with depth (0.0581°C/m) (Fig. F23). Heat flow, which was calculated by taking into account thermal conductivity measured on cores, is 62 mW/m2. Site C0011The main reasons for returning to Site C0011 were to perform temperature measurements for heat flow determination and expand the age-depth models into the Pliocene and Quaternary. This was necessary because as the upper stratigraphic intervals (upper Shikoku Basin facies) were not adequately sampled during Expedition 322. The additional coring provides complete profiles of organic and interstitial water geochemistry, and samples across prominent discontinuities in physical properties identified on LWD data. Site C0011 is located on the northern flank of the Kashinosaki Knoll (Fig. F24, F25). OperationsTransponders were retrieved from 0600 to 1530 h on 17 December 2010. The Chikyu then moved to Site C0011's first transponder location over a 22 nmi distance at an average speed of 5.5 kt. The ship began setting transponders at 1930 h and finished at 0700 h on December 18. The HPCS/EPCS/ESCS coring assembly was made up, run into Hole C0011C, and tagged the seafloor at 1700 h; coring began at 1800 h on 18 December. After oil leakage from the HPCS was found, the decision was made to pull out to 13 m above the seafloor, and coring in Hole C0011C ended at 22.5 mbsf. From 0015 h on 19 December, the BHA was jetted in Hole C0011D to 6 mbsf and drilled in to 21 mbsf before starting HPCS coring again at 0245 h. Coring continued to 184.5 m DSF where the decision was made to switch to EPCS because of the continuous partial penetrations. However, EPCS coring did not bring good quality and recovery cores, and we switched to the ESCS after three cores at 1200 h on 21 December. After reaching 380 mbsf, which is 30 m deeper than the target depth, coring was stopped at 0900 h on 24 December, and we spotted the kill mud and displaced same with seawater before pulling out. Core bit and all assembly were on rig floor at 2000 h. Coring operations were smooth except for oil leakage from the HPCS, which forced us to end Hole C0011C at a very shallow depth. Core recovery was good with an overall average of 101.7% in Hole C0011C and 102.2% in Hole C0011D. HPCS cores were the best of the three different core types in terms of both recovery and quality, with an average recovery of 102.4%, ranging from 117.3% to 82.8%. EPCS did not get good core recovery, ranging from 77.2% to 38.6%. ESCS cores were good in recovery with an average of 103.3%, ranging from 158.6% to 9.3%, and remarkably good cores were obtained in the weakly cemented tuffaceous sandstone, an improvement over Expedition 322 RCB coring. There were two incidents of core liner broken, and core jammed once. LithologyA total of 380 m of strata was drilled in Holes C0011C and C0011D (Fig. F26). Two lithologic units were identified with very good recovery rates. Unit I corresponds to Shikoku Basin hemipelagites and Unit II corresponds to middle Shikoku Basin volcanic sand facies (Underwood et al., 2010). In addition, two lithologic subunits were interpreted within Unit I, Subunit IA (youngest), and Subunit IB. Cored lithologies include silty clay, clay, and mudstone interbedded with coarse to fine volcanic ash (Fig. F26). The Subunit IA/IB boundary occurs at 251.56 m core depth below seafloor, Method B (CSF-B) and is defined by the appearance (below) of harder dark gray mud and mudstone with abundant bioturbation and by the disappearance of volcanic ash layers with unaltered glass. A more dramatic lithologic change occurs below 347.82 m CSF-B where we found an abrupt shift into coarser-grained tuffaceous sandstone and heterolithic gravel and sand. This change marks the Unit I/II boundary. Unit I was not cored during Expedition 322. Subunit IA comprises a 251 m thick succession of greenish gray silty clay with minor amounts of grayish silty clay and <50 cm intercalations of volcanic ash, often bearing unaltered glass shards. Bioturbation is particularly observed in the upper part of the unit. The genera Zoophycos and Chondrites burrows are abundant. Overall, ash layers are more abundant in the upper half of the subunit to ~100 m CSF-B (Fig. F26). In addition, XRD data from the dominant silty clay lithology indicate an average content of 57% clay minerals, 18% quartz and plagioclase, and 7% calcite for the subunit. However, both variations in the relative percentage of calcite are recorded at specific intervals with a maximum in calcite abundance of 26% at 3.16 m CSF-B (Fig. F27). Although uncommon, siliceous fossils (diatoms, radiolarians, and sponge spicules) are present in Subunit IA. The dominant lithology of Subunit IB is a greenish brown to dark gray weakly lithified mudstone with minor contribution of altered volcanic ash beds (Fig. F26). Clay minerals and altered volcanic glass are the most abundant particles on smear slides and an increase in the severity of glass alteration as depth increases is observed below the transition from Subunit IA to IB (Fig. F28). Clay content from XRD data averages 67% for the mudstone, ranging from 74% to 46% (Fig. F27). Quartz content ranges from 12% to 19% and averages 17%, and plagioclase ranges from 9% to 18% and averages 12%. Calcite is present in the subunit, varying from 0% to 31% (Figs. F27) and reaching a maximum near the transition from Subunit IA to IB. Siliceous microfossils are absent from smear slides (with one exception) in Subunit IB. The upper part of Unit II is dominated by coarser-grained tuffaceous sandstones and heterolithic gravel, gravelly sandstone, and sandstones with sharp and well-defined upper and lower boundaries (Fig. F29), similar to recoveries during Expedition 322. These beds are separated by indurated mudstone very similar to that of Subunit IB. The relative clay mineral abundance drops in association with a higher percentage of sandy material. From XRD data, the content of quartz is consistent at ~16%, whereas plagioclase values vary from 11% to 46%. Biotite, orthopyroxene, and hornblende are common in the tuffaceous sandstones (Fig. F26). Siliceous microfossils and fresh glass shards are found again in Unit II. Four volcanic ash layers comprise stratigraphic markers at Site C0011. The first ash layer, which correlates with the Azuki volcanic ash layer on land (0.85 Ma; Hayashida et al., 1996), occurs at 21.77 m CSF-B (Fig. F29). The second ash layer, which the Pink ash correlates with (1.05 Ma; Hayashida et al., 1996), occurs at 31.32 m CSF-B. The correlative products of both events are preserved on land as thin discrete accumulations of ash. In addition, a bed correlative to the onland Ohta ash layer (4.0 Ma; Satoguchi et al., 2005) is present at 158.6 m CSF-B and a provisional match to the onland Habutaki ash layer (2.8-2.9 Ma; Satoguchi et al., 2005) is located at 76.825 m CSF-B. XRF analyses were performed on 57 samples from Holes C0011C and C0011D to estimate the bulk chemical composition of the sediments and to characterize compositional trends with depth and/or lithologic characteristics (Fig. F30). As shown by the underlying units (Underwood et al., 2010), major element contents in the hemipelagic mud and mudstone of Unit I span a relatively small range of values, and the compositions resemble those of the upper continental crust as defined by Taylor and McLennan (1985). A few samples of volcanic ash and volcaniclastic layers were analyzed. They all have higher silica and lower aluminum content than the background sediment and slightly lower iron content but variable alkaline content. Several samples have a high-potassium rhyolite composition. Other samples, and notably the tuffaceous sandstones in Unit II, have relatively high sodium and calcium but low potassium content and correspond to more typical calco-alkaline rhyolite and dacite compositions. This variability in bulk chemistry suggests that volcanic materials originate from different sources (presumably Kyushu vs. Izu-Bonin). The deposition mode for Subunit IA was dominated by hemipelagic settling. A small MTD is observed in the uppermost few meters of Holes C0011C and C0011D, between 0.85 and 2.77 m CSF-B (Core 333-C0011C-1H). However, several volcanic ash layers display turbidite characteristics (basal lamination and upward fining), suggesting these were remobilized by subaqueous gravity flow. Deposition of Subunit IB was dominated by hemipelagic settling with minor contributions of volcanic coarse sand-sized ash and fine (silt- and clay-sized) ash that becomes more abundant toward the base of the subunit. During the deposition of the upper part of Unit II, the paleoenvironment was dominated by transport of sand from a volcanic source. Miocene sandy turbidites have been previously identified in the Nankai Trough and Shikoku Basin. The Miocene siliciclastic turbidites at Site 1177 are generally older and were derived from a relatively large land mass, most likely southern Japan. That middle–late Miocene (15–7 Ma) dispersal system spread terrigenous sediment over a broad area of the Shikoku Basin (Moore, Taira, Klaus, et al., 2001; Fergusson, 2003). Conversely, the younger tuffaceous sandstones at Site C0011, on the northeast side of the basin, have been linked to a provenance in the Izu-Bonin volcanic arc (Underwood et al., 2010). Structural geologyHoles C0011C and C0011D provide sparse and subtle structures. Structural features encountered in Hole C0011B are subhorizontal to moderately dipping beds, high- to moderately dipping small faults, planar shear zones, and low-angle healed faults (found in lithologic Subunit IB and Unit II) (Fig. F31). Sediment-fill veins (vein structures) also develop in the shallow part. Most faults and shear zones are observed over the 30–190 m CSF interval, which may be in part due to better observations on HPCS rather than ESCS cores. Two conjugate sets of northwest–southeast and north-northeast–south-southwest striking normal faults can be distinguished (Fig. F32). The strikes of these conjugate sets are, respectively, orthogonal to Nankai subduction convergence (300°–310°N; Miyazaki and Heki, 2001; Henry et al. 2001; Loveless and Meade, 2010) and orthogonal to the local direction of compression inferred from kinematic modeling of the Zenisu-Izu fault system (20°N; Mazzotti et al., 2001). It is therefore possible that the state of stress at Site C0011 is influenced by intraplate deformation within the Philippine Sea plate. PaleomagnetismShipboard paleomagnetic studies for Holes C0011C and C0011D were performed with remanent magnetization and magnetic susceptibility measurements of discrete samples. Recovered sediments showed considerable variations in magnetic properties and demagnetization behavior in Holes C0011C and C0011D. Because AF demagnetization of 30 mT can effectively remove drilling-induced remagnetization, the remanent magnetization of 30 mT inclinations were used for magnetostratigraphy. Based on our data, the geologic age throughout the cores is from 0 to ~7 Ma (Fig. F33). An average sedimentation rate in the cores is calculated at ~4.6 cm/k.y. The sedimentation rate changes rapidly downhole from ~2.7 cm/k.y. to ~7.5 cm/k.y. at ~80 m CSF-B (or ~3.0 Ma). Physical propertiesBulk density and resistivity values generally increase from the surface to 50 m CSF, reflecting normal consolidation of sediments (Fig. F34). However, from ~50 to 80 m CSF density and resistivity decrease and then remain anomalously constant from 80 to 240 m CSF. Below 240 m CSF, density and resistivity increase abruptly and then continue along a normal consolidation trend. This behavior is similar to that observed at Ocean Drilling Program (ODP) Leg 190 Sites 1173 and 1177, where the base of the zone showing retarded compaction was ascribed to dissolution of opal-CT cement (Spinelli et al., 2007). Sediment strength generally increases with depth, though vane shear and penetrometer measurements could not be made below 160 m CSF because of high sediment strength (Fig. F35). Resistivity and acoustic velocity measurements conducted on discrete cubes from below 215 m CSF show normal trends of increasing resistivity and velocity with depth, including elevated resistivity and velocity in volcaniclastic sands at the top of Unit II (Fig. F36). Anisotropies in the vertical plane show that with depth the z-direction becomes slower and more resistive, which is consistent with uniaxial consolidation of transversely isotropic, bedded sediments. Two transitions were shown by LWD data at Site C0011, one at 212 m LSF (downward decrease in gamma ray with a small associated decrease in resistivity) and one at 251.5 m LSF (downward increase in resistivity and gamma ray). The transition at 251.5 m LSF is obviously associated with the strong porosity and resistivity gradient observed between Subunits IA and IB. At this date, the upper transition is not correlated with any remarkable observations on cores except, perhaps, a 1 m thick silt layer at 200.4–201.4 m CSF. During HPCS operations, downhole temperature was measured with the APCT-3 at ~30 m intervals. We completed one measurement in Hole C0011C at 22.5 mbsf and eight measurements in Hole C0011D from 49 to 184 mbsf. Data show a nearly linear increase in temperature with depth (0.0913°C/m) (Fig. F23), corresponding to a heat flow value of 89.5 mW/m2. Temperature extrapolated at basement (~1050 m, from seismic profile), taking into account heat conductivity variations in the cored intervals, is ~80°C. Inorganic geochemistryInorganic geochemical objectives at this site were to document the variations in interstitial water chemical composition in shallower depth, which were recovered during Expedition 322. Whole-round lengths ranged from 19 to 41 cm and pore water volumes per centimeter of core range from 1.7 to 2.8 mL/cm between 0 and 378.6 m CSF (Fig. F37). Because of the more consolidated nature of the formation in the deeper portion of this site and the coring techniques used, some of the deeper cores were quite disturbed. We were able to use sulfate concentrations to identify and quantify contamination in the deeper cores. Results are generally consistent between Hole C0011B (Expedition 322) and Holes C0011C/C0011D (Expedition 333) data, except for bromide, for which there is an offset, still unexplained. Chlorinity increases rapidly with depth in the upper ~25 m of Holes C0011C and C0011D, stays close to seawater value from 25 to 250 m CSF in Hole C0011D, and then gradually decreases below 130 m CSF in Hole C0011D (Fig. F38). The chlorinity decrease, which continues to the deeper interstitial waters of Hole C0011B taken during Expedition 322, may reflect the updip migration of interstitial water freshened by the smectite-illite reaction at greater depths below the trench and prism toe. Another remarkable feature is a sharp drop in silica concentration (also coincidental with a lithium concentration maximum) at the level of the transition from lithologic Subunit IA to IB (Fig. F39). Remarkably, this drop correlates with a decrease in porosity from ~65% to ~55% observed over <10 m in moisture and density data as well as with a concurrent resistivity increase in LWD and core data. The high (~800 mM) silica concentration in the fluid in Subunit IA supports the hypothesis that the retarded compaction in lithologic Subunit IA is due to a opal-CT cement, as proposed for Sites 1173 and 1177 (Spinelli et al., 2007). At the level of the tuffaceous sandstones (350–370 mbsf), a secondary silica concentration maximum is observed, which may be related to ash alteration. This interval is also characterized by higher barium concentration and slightly decreased lithium and strontium relative to the trend defined from concentrations above and below. Organic geochemistryMethane was the only hydrocarbon gas detected at Site C0011 and it occurs only in low concentrations (2 ppmv) in the uppermost 250 m of the cored sequence (Fig. F40). Thereafter, methane concentration gradually increased to reach highest values (~900 ppmv) at 380 m CSF. TOC, TN, and TS contents are generally low in all lithologic units, averaging 0.31 ± 0.10, 0.06 ± 0.01 and 0.14 ± 0.97 wt%, respectively (Fig. F41). At the base of Subunit IA and top of Subunit IB, several samples display higher TS values, including a pyrite-rich specimen at ~12 wt%. Carbon to nitrogen ratios (TOC/TN) were 5.67 ± 1.60, indicating a marine origin for the sedimentary organic matter. The calcium carbon content varied between 0.2 and 24.5 wt% and shows highest concentration in the upper part of Subunit IA and over the transition from Subunit IA to IB. Rock-Eval derived Tmax values range from 399° to 414°C and indicate a thermally immature state of the organic matter. Site C0012The main objectives of returning to Site C0012 were to perform temperature measurements for heat flow determination, to expand the age-depth models into the Pliocene and Quaternary, and to core the basement to at least 100 m below the sediment/basement interface. Knowledge of thermal state, interstitial water geochemistry, hydrologic properties, and basement alteration are needed to characterize the state of the subuction inputs and model their evolution with downdip increases in temperature and pressure. OperationsWithout picking up the transponders from Site C0011, the Chikyu moved to Site C0012 after the coring assembly was retrieved on board at 1930 h on 24 December 2010. Transit in dynamic positioning (DP) mode over a distance of 5 nmi at 5 kt finished at 2030 h. From 2200 h, transponders were dropped and set at four different locations and calibrated. The location was set at 0815 h on 25 December upon finishing of DP calibration. The HPCS/EPCS/ESCS coring assembly was made up and run into Hole C0012C to 3528 m drilling depth below rig floor (DRF). After tagging the seafloor at 3540.5 m DRF at 1600 h, HPCS coring began at 1630 h. After coring the eleventh core, a hydraulic piston system motor malfunction caused a delay from 1300 to 1500 h. After coring the fifteenth core at 2130 h, the core wire parted when the sinker bar assembly was overloaded. Hence, the sinker bar fell to the bottom of the hole and the damaged core line was cut at ~100 m. The hole was abandoned after spotting kill mud. The Chikyu moved to Hole C0012D while waiting on weather from 0600 to 0800 h on 27 December. Test coring was done at seafloor at 1000 h and washed down to 20 mbsf at 1330 h and then drilled down to 118 mbsf. HPCS coring began at 1745 h and continued to 180 mbsf, where strong wind caused ship offset by ~16 m and stopped coring at this hole. We pulled out of Hole C0012D above the seafloor at 1900 h and waited on weather. The Chikyu moved to Hole C0012E and the decision was made to drill down and core the sediment/basement interface with the ESCS to make the best use of a short good weather window. Hole C0012E was spudded at 1030 h on 29 December, washed down to 28.5 mbsf, and then drilled to 500 mbsf, which was reached at 1045 h on 30 December. After preparation for coring, the first ESCS core was taken at 1415 h and coring continued to 528.5 mbsf. Coring was stopped at 2245 h because of deterioration of the weather and the BHA was pulled out of hole. Making up the RCB coring assembly for Hole C0012F started at 0230 h on 1 January 2011 while waiting on weather. The BHA was run to 3530 m DRF, spudded at 1315 h, and drilled to 520 mbsf. RCB coring began at 1500 h on 2 January but ended at 1930 h after the second core was taken because of abnormal pressure while coring. After cleaning the outer core barrel and the hole, the center bit assembly was set for a circulation test. The test was successful, but the center bit assembly could not be retrieved because the pull bar broke, which ended coring operations in Hole C0012F. Pulling out of the hole took place between 0730 and 1615 h. The RCB coring assembly for Hole C0012G was made with a roller cone bit after finding out that more than half of the teeth on the polycrystalline diamond compact drill bit (PDC) used in Hole C0012F were worn out. Running pipe down started at 1815 h on 3 January, and Hole C0012G was spudded at 0900 h on 4 January. We drilled to 515 mbsf and began RCB coring with full advance at 1315 h on 5 January. Full advance coring continued to 591 mbsf with medium to poor recovery. We then switched to a shorter advance to improve core recovery to 630.5 mbsf. Coring in Hole C0012G ended at 1545 h on 7 January, and kill mud spotting and pulling out of the hole lasted until 0330 h on 8 January. Coring operations were disturbed twice by short intervals of low-pressure weather. In addition to weather, there were two incidents that forced us to pull out of the hole: a parted core wire and a parted center bit at the bottom. Core quality and recovery varied depending on the formation or lithology and also with corer and drill bit types. Core recovery was excellent for the piston cores in Holes C0012C and C0012D, with average rates of 103.3% and 104%, respectively, and also presents a marked improvement in quality from Expedition 322 RCB coring. In comparison to Site C0011, cores from Site C0012 had almost constant recovery without broken cores or becoming jammed. However, Cores 333-C0012D-8H to 13H (bottom of Hole C0012D) were affected by coring disturbance (flow in and stretching). ESCS was used in Hole C0012E to core only at the sediment/basement interface and yielded the best quality cores compared to three other attempts with RCB. Average recovery was 48.6%, ranging from 11.4% to 87.9%. Holes C0012F and C0012G used RCB coring but with different bits. RCB coring with a damaged PDC bit in Hole C0012F yielded two cores with an average recovery of 48.2%. Hole C0012G was cored deep into the basaltic basement with a roller cone bit. Core recovery was 22.4% in average, varied between 9.6% and 45.8% for the full advance cores, and varied between 4.1% and 73.2% for the half advance in the deeper part of the hole. LithologyIn Holes C0012C and C0012D, 180 m of lithologic Unit I (Shikoku Basin hemipelagites) and the upper part of lithologic Unit II (middle Shikoku Basin volcanic sand facies) were drilled during Expedition 333 (Fig. F42). The remaining holes (C0012E, C0012F, and C0012G) aimed at drilling red calcareous claystone and basalt at the contact between sediments in the Shikoku Basin and the igneous oceanic crust. The cores brought new information on lithologic Unit I not acquired during Expedition 322 because of severe coring disturbance and poor recovery. Three lithologic subunits were interpreted in Unit I: Subunit IA (youngest), Subunit IB, and Subunit IC. The subunits are distinguished based on the presence, frequency of occurrence, and thickness of volcanic ash layers. The lithologies in Holes C0012C and C0012D include dark greenish gray clay and silty clay and silt interbedded with volcanic ash and minor occurrences of thin sand. A major change in the frequency of the occurrence of ash layers is recorded at ~71.5 m CSF, thereby defining the Subunit IA/IB boundary. Ash alteration was observed from 91.2 m CSF-B to the lower part of Subunit IB. Within Subunit IB, ash layers are scarce to ~124.2 m CSF, below which another interval of dark greenish gray clay/silty clay with abundant ash layers extends to 151.61 m CSF-B. This depth for the base of Unit I matches closely with the designation of 150.9 m CSF that was made during Expedition 322 (Underwood et al., 2010). Beginning at 151.61 m CSF, Unit II comprises turbidite sands and sandstones with sharp and well-defined upper and lower boundaries. Commonly, beds have normal grading, but some are intercalated with intervals of massive beds with or without clay clasts. At the base of normal graded beds, pebble and sand clasts are composed of coarse ash and lapilli tuff. The lower part of Unit II comprises several layers of carbonate-cemented sandstones with calcite and barite veins. These beds are separated by mudstone very similar to that of Subunit IC. The base of Unit II was not cored during Expedition 333 but was fixed at 219.8 m CSF in Hole C0012A (Underwood et al., 2010). Nannofossils are the dominant group of microfossils and are found in both Units I and II. Sponge spicules, diatoms, and radiolarians occur as a rare or trace component in most of Subunit IA, being relatively more abundant at the top of the subunit. Below ~85 m CSF-B they were not identified. Bulk powder XRD data indicate an average content of 63% clay minerals, with the lowest content (~45%) characterizing the uppermost 15 m. There is on average about 19% quartz and 18% plagioclase; both show uniform values throughout Units I and II (Fig. F43). The calcite content is highest in the upper 15 m, where it reaches ~25% (Figs. F43). Below 15 m CSF the calcite content of Subunit IA is very low, dropping the average for the subunit to 4% except for Subunit IB where it varies from 0% to 20% and averages 6%. Major element concentrations of Unit I and II from XRF analyses span a relatively small range of values (Fig. F44) and resemble those of the upper continental crust as defined by Taylor and McLennan (1985). The cored portion of Units I and II has an estimated Holocene–late Miocene age (~0–8.3 Ma). The Azuki volcanic ash bed, dated on land as 850.000–900.000 y (Yoshikawa and Mitamura, 1999) was identified at 5.7 m CSF-B. The Pink ash bed, dated on land as 0.99–1.05 Ma (Yoshikawa and Mitamura, 1999), correlates with an ash layer at 7.7 m CSF-B. A third major volcaniclastic event, the Ohta ash bed, dated on land as 4.0 Ma (Satoguchi et al., 2005), seems to coincide with an ash bed at 44.04 m CSF-B (Fig. F42).The depth of the presumed Azuki and Pink ash beds implies very slow sedimentation rates over the last ~1 Ma. This interpretation is, however, consistent with the depth of the Brunhes-Matuyama reversal and of the Jaramillo Chron from natural magnetic remanence data. This interval of condensed sedimentation lies on an angular unconformity and hiatus at ~15 m CSF, interpreted as the top of a slump. Other, yet unresolved, hiatuses may account for the very slow apparent sedimentation rate above this unconformity. The deposition of Subunits IA and IC was dominated by hemipelagic settling and frequent volcanic eruptions, whereas the time interval of Subunit IB experienced fewer volcanic eruptions. During deposition of the upper part of Unit II, the paleoenvironment was dominated by deposition from a sandy system with a volcanic provenance. In comparison to Holes C0011C and C0011D, the Miocene sandy turbidites are finer grained on top of the bathymetric high and the thick tuffaceous sandstone layers characteristic of the middle Shikoku Basin facies were not observed. On the other hand, pebbly and mixed layers evocative of MTDs were found. Hole C0012E recovered two cores of greenish yellow mudstone intercalated with thin sandstone layers from 500 m CSF, corresponding to the base of lithologic Unit V (volcaniclastic-rich facies) defined during Expedition 322 (Underwood et al., 2010), and one core from 519 m CSF that recovered 6.8 m of reddish brown calcareous claystone with lighter green layers, overlying altered pillow basalts. The interface between the red calcareous claystone and the basaltic basement was also recovered in Holes C0012G and C0012F. The red calcareous claystone corresponds to Expedition 322 lithologic Unit VI (pelagic claystone) (Underwood et al., 2010) and holds veins of calcite with traces of barite as well as several layers with accumulations of manganese oxide forming millimeter- to centimeter-sized lumps. As observed during Expedition 322, the basalt is highly altered and some voids remaining between basalt pillows are filled with analcime. Hole C0012G cored pillows and massive phyric basalts from 525.69 m CSF to the base of the hole at 630.5 m CSF. Observations of thin sections showed that all olivine and glass (except in one sample) as well as a large fraction of the plagioclases have been replaced by secondary phases—dominantly saponite and zeolites—that are also present as vesicle fillings. The basalt experienced localized alteration under iron oxidizing conditions with accumulation of iron hydroxides in veins, but most of the rock mass was pervasively altered under reducing conditions forming saponite and, locally, pyrite. A more complete description will be available after the shore-based sampling party planned at Kochi Core Center. Structural geologyStructures observed at Site C0012 mainly consist of bedding planes, faults, shear zones, and chaotic structures (Fig. F45). Bedding planes show a large range of dipping angles from 3° to 70° but are organized in zones of low and high bedding dips. Bedding planes with low dips are characteristically observed in Zone I (0–15 m CSF) (Fig. F45B) and Zone III (85–145 m CSF). However, high dip angle beds are found in Zone II (15–85 m CSF), where they consistently strike northeast–southwest (Fig. F45C) and dip southeast, and in Zone IV (145–180 m CSF) where the distribution of strikes and dips appears scattered. There is an angular unconformity between Zone I low-angle bedding and Zone II high-angle bedding. Faults are mostly normal faults with high dip angles, striking northwest–southeast, and dipping northeast or southwest, suggesting northeast–southwest extension (Fig. F45D). Shear zones generally have high dip angles with large displacements. Chaotic structures are composed of disrupted beds, folds, and injections of sand or mud and observed at the bottom of Zone II and Zone IV. Considering the location of Site C0012 on a topographic high southwest of a steep slope evocative of a slide scar, one interpretation proposed is that Zone II corresponds to a slump that was later covered by flat-lying sediments, whereas Zone IV may have been affected by multiple (and older) sliding events. Paleomagnetic data suggests that the unconformity between Zone I and Zone II correlates with an age hiatus. Similar observations within the upper part of Unit III during Expedition 322 suggested that a slumping event associated with the remobilization of the uppermost sedimentary layers also occurred about 9.5 m.y. ago (Underwood et al., 2010). PaleomagnetismPaleomagnetic shipboard studies for Site C0012 were performed with remanent magnetization and magnetic susceptibility measurements of discrete samples (Fig. F46). Magnetostratigraphic correlations indicate the age of the sediments in Holes C0012C and C0012D range from present day at the seafloor to >8 Ma at the bottom of the hole (~180 m CSF). Following AF demagnetization to 30 mT, inclination values were variable. Bedding correction performed on the specimens clustered the data near the expected ~52° but did not affect the chron and subchron boundaries. The Bruhnes/Matuyama boundary was detected in Core 333-C0012C-2H, and tephra chronology identified the Pink tephra layer in Core 333-C0012C-3H within the lower portion of the Jaramillo Subchron and the Ohta tephra layer in Core 333-C0012C-6H within the Gilbert Chron. A thickness of only 9 m between these two chrons indicates that the lower section of the Matuyama Chron is probably missing. Correlation of the magnetic susceptibility between Sites C0011 and C0012 indicates a hiatus at ~14 m CSF at Site C0012, spanning roughly 2 m.y. (1.07–3 Ma), coincident with an angular unconformity (Fig. F46). Below this level, the sedimentation rate displays some variations, notably a possible hiatus at the base of the slump (~5 Ma), and faster sedimentation rates in lithologic Unit II before 7.4 Ma. Physical propertiesFrom the surface to ~10 m CSF, porosity decreases downhole, as expected for progressive burial. Below 10 m CSF, porosity slightly increases and then remains relatively constant until ~70 m CSF, which coincides with the lithologic Subunit IA/IB boundary (Fig. F47). Within this anomalous interval, electrical resistivity also remains constant while shear strength increases, and there is an anomalous shift in the concentration of dissolved silica. Between 70 and 100 m CSF, porosity sharply decreases and electrical resistivity and shear strength increase. Porosity increases and then decreases between 100 and 170 m CSF, followed by a steady compaction trend, with some scatter in sand-rich units, to the base of the borehole. Sandstones are also indicated by spikes of high magnetic susceptibility and low natural gamma ray. Site C0012 porosity values from below 240 m CSF are generally lower than those from similar depths at Site C0011 (Fig. F48). A possible explanation for the lower porosity at Site C0012 is removal of overlying material by erosion or slope failure. This interpretation would be consistent with the observed time gap of ~2 m.y. found between 12 and 18 m CSF and the structural evidence of an angular unconformity. Claystones from below 500 m CSF range in porosity from 0.28 to 0.46 and show P-wave velocities ~2000 m/s (Fig. F49). Within the basalt, measured porosity is extremely variable and ranges from 0.09 to 0.37. Measured P-wave velocities vary between 3000 and 5000 m/s. Electrical resistivity is greater in the z-direction within the claystones but lower within the basement. Higher resistivity in the z-direction in the sediments is consistent with a transversely isotropic medium in which the bedding planes are approximately horizontal (Fig. F49). Within the basement, electrical conductivity may be enhanced by subvertical veins or fractures filled with more conductive material, resulting in a lower resistivity in the z-direction. Thermal gradient values are evaluated from the APCT-3 measurements made at 10 depths in Holes C0012C and C0012D together, and the mean thermal gradient value determined is 0.135 K/m (Fig. F23). The estimated heat flow value at this site is 141 mW/m2, amounting to ~50% higher than the 89.5 mW/m2 determined for the adjacent Hole C0011C that was drilled during this expedition. Based on the determined heat flow value of 141 mW/m2, as well as the thermal conductivity values that we have obtained on board by core measurements, temperature at the top of basement (at 526 m CSF) is estimated to be ~65°C, which is significantly lower than the estimated value of 80°C at Site C0011. We suspect that fluid convection, perhaps occurring in the basement, is transferring heat between the two sites, thus resulting in a higher heat flow at Site C0012, which is located on the topographic high. However, the effect on heat flow of sedimentation and also of sediment removal by gravity sliding at Site C0012, should also be considered in models. Inorganic geochemistryThe main objective of the inorganic geochemistry program at this site was to document the geochemical properties of subduction inputs at a site located above a basement high, near the crest of the Kashinosaki Knoll. A total of 28 pore fluid samples were squeezed from selected whole-round sections for chemical and isotopic analyses. To obtain enough interstitial water for shipboard and shore-based analyses, 19–31 cm long sections were squeezed in Holes C0012C and C0012D. In the red claystone located directly above the basement in Hole C0012E, sections 59.5–61 cm in length were squeezed. Pore fluid volumes per length of interstitial water section decrease with depth, from 2.75 to 0.71 mL/cm of core in the upper ~180 m CSF of Holes C0012C and C0012D (Fig. F50). In the deeper material above the basement, volumes were lower, ranging from 0.22 to 0.08 mL/cm. The sulfate profile for Site C0012 documents a much deeper sulfate reduction zone than observed at the other sites drilled during this expedition. During Expedition 322 it was observed that minimum sulfate concentration, which occurs at ~300 m CSF at Site C0012, coincided with a marked increase in methane concentration (Saito et al., 2010). The Expedition 322 scientists interpreted the sulfate profile at Site C0012 as being driven locally by anaerobic methane oxidation. The deeper anomaly may be attributed to lower sedimentation rates (because of the bathymetric high Site C0012 sits on), to a lower average organic matter content at Site C0012, or to differences in fluid migration. Additionally, in both Holes C0012E and C0012A sulfate increases in concentration in the interval below ~450 m CSF, which may indicate diffusion from fluid in basaltic basement with a higher sulfate concentration. In general, analytical results are consistent between Expeditions 333 and 322 (Figs. F51, F52) and interpretations proposed after Expedition 322 are not put in question by the newly acquired data. However, shipboard Br concentrations during Expedition 333 tend to be systematically lower, whereas Li and Sr concentrations tend to be higher. Overall, the combined data set reflects in situ alteration of volcanic ash alteration in the sediment and basalt alteration in the crust as well as exchange by diffusion. More specifically, the decrease in Mg and K, increase in Li and Sr, and variations in silica (Fig. F52) in the upper 200 m are probably controlled by volcanic ash alteration and equilibration of the pore fluid with clay minerals. Silica concentration drops below the Subunit IA/IB boundary at ~70 m, where a decrease in porosity and an increase in resistivity are also observed. This again suggests a relationship between pore fluid composition and the presence of opal cement. However, the silica concentration remains relatively high and variable in the 200–500 mM range from 90 to 200 m and then, according to Expedition 322 data, decreases again. These variations would not be well explained by existing models for opal dissolution and quartz precipitation (Spinelli et al., 2007). This suggests that other sources of silica are present (e.g., volcanic ash alteration) and that silica concentration in this interval is not limited by quartz precipitation. The trend of increasing chlorinity (Fig. F51), Ca, and Sr (Fig. F52) concentration and decreasing Na in the lower part of the borehole is interpreted as a consequence of diffusion between sediment and basement fluids. Organic geochemistryAt Site C0012, methane and ethane were either below detection or present at only low concentrations. No heavier hydrocarbon gases (i.e., C3 and C4) were found. The only two samples that contained both methane and ethane were found at depths of ~501 and ~520 m CSF and had C1/C2 ratios <100, indicating a possible thermogenic origin of these hydrocarbon gases (Fig. F53). Calcium carbonate (CaCO3) concentrations ranged between 0.2 and 45.1 wt% and averaged 6.1 wt% (Fig. F54). Sediment below 500 m CSF contained higher amounts of CaCO3 compared to the upper 180 m CSF of the cored sequence. TOC, TN, and TS concentrations were low, ranging between 0.03 and 0.46 wt%, 0.03 and 0.07 wt%, and 0 and 0.49 wt%, respectively. The TOC/TNat fell in the range of 1.3–9.3, suggesting a marine origin of the organic matter. The variations of these four elemental parameters shared a similar pattern, including scattered values but displaying a generally increasing trend with depth in the upper 52 m CSF, relatively uniform values between 52 and 180 m CSF, as well as low values between ~500 and 525 m CSF. |
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inch HPCS/EPCS/ESCS bottom-hole assembly (BHA) was run into Hole C0018A at 1445 h on 11 December. Coring began at 0115 h on 12 December and continued to the 36th core, and we decided to finish at 314.15 mbsf at 2103 h on 16 December (Table