- 1School of Marine Sciences, Sun Yat-Sen University, Zhuhai, China
- 2Southern Marine Science and Engineering Guangdong Laboratory (Zhuhai), Guangdong, China
- 3Guangdong Provincial Key Laboratory of Marine Resources and Coastal Engineering, Guangzhou, China
- 4Pilot National Laboratory for Marine Science and Technology, Qingdao, China
- 5Polar and Marine Research Institute, College of Harbor and Coastal Engineering, Jimei University, Xiamen, China
Distribution of calcium carbonate (CaCO3) in marine sediment has been studied over the last century, and influence by multiple factors with regard to dissolution and dilution of sedimentary CaCO3 has long been established. There is still lack of quantification on the influence of those factors, so it remains elusive to determine which specific process is driving the down-core variation of CaCO3 content (wtCaCO3%) records. Here, based on a newly compiled CaCO3 data set and a carbonate model, depth-profiles of sedimentary wtCaCO3% from the West Pacific Ocean can be well illustrated, and influence from different factors on their distribution features can be quantified. The deep ocean circulation is found to largely shape the inter-basin disparity in sedimentary wtCaCO3% distribution between the equatorial regions (e.g., the Western Equatorial Pacific Ocean and the Central Pacific Ocean) and the north–west regions (the Philippine Sea and the Northwest Pacific Ocean) in our study region. Moreover, the slow carbonate dissolution rate in the deep Central Pacific Ocean guarantees better accumulation of CaCO3 at depth compared to that in other regions. However, enhanced dilution by non-carbonate materials of sedimentary CaCO3 on a topographic complex can potentially obstruct the dissolution profiles constituted by sedimentary wtCaCO3% in the pelagic ocean. The aforementioned assertion suggests that changes of wtCaCO3% accumulation in marine sediment in the West Pacific Ocean can be used to dictate past changes of the deep ocean circulation (2,500 to 3,000 m) in this area but constraint on the non-carbonate flux, especially on the topographic complex, should be necessary.
Introduction
The global ocean is actively involved in the climate regulation by influencing the carbon cycling on the Earth’s surface on different time scales (Regnier et al., 2013). Processes governing the carbon sequestration from the lower atmosphere to the ocean and cycles of carbon in the ocean interior are mainly known as the biological pump and the solubility/physical pump, respectively. In particular, the biological pump transforms dissolved inorganic carbon into particulate organic carbon in the surface ocean, transfers the particulate organic carbon (POC) to depth via settling particles, and releases the sequestrated carbon back into the sea water as CO2 by microbial metabolism/respiration (POC remineralization) (Volk and Hoffert, 1985). In contrast, the solubility/physical pump regulates carbon partition between the lower atmosphere and the surface ocean by CO2 exchange (Ito and Follows, 2003), transports carbon from the surface ocean to the deep ocean by deep convection (deep water formation), and circulates carbon in deep ocean basins by the global ocean conveyor belt (thermohaline circulation).
The Pacific Ocean, which is the biggest marine carbon reservoir at the end of the global ocean conveyor belt, hosts the oldest and carbon-rich deep water in the global ocean owing to accumulated organic matter remineralization (Yu et al., 2020). The corrosive Pacific deep water (Sexton and Barker, 2012) results in shallower preservation depth of calcite (rarer and more soluble aragonite is excluded in our analysis), which hereafter is the only carbonate mineral considered in this article, in the Pacific sediments than that in the Atlantic and Indian ocean sediments (Berger et al., 1976; Biscaye et al., 1976; Kolla et al., 1976). Features regarding the spatial distribution of Pacific sedimentary CaCO3 content (wtCaCO3%) have long been discovered to be related to multiple factors (e.g., ocean productivity, ocean circulation, and lithogenic dilution), while their impacts have not been quantified (Broecker, 2008). Given the importance of the Pacific Ocean in the global carbon cycle, especially during the climate transition periods (e.g., the suggested CO2 outgassing way to the atmosphere from the abyss during the last deglaciation; Gray et al., 2018), it is necessary to conduct a quantitative assessment on the carbonate distribution in the deep Pacific Ocean, in order to establish the basis to examine past changes of the Pacific carbonate system.
Sedimentary CaCO3 in the deep sea mainly consists of calcite or aragonite sourced from calcifying plankton. Theoretically, the upper water column of the ocean is saturated with regard to CaCO3, and critical dissolution of calcite takes place below a horizon where the sea water becomes calcite-under-saturated as a result of increased solubility of calcite with water depth (pressure). Under-saturation of CaCO3 could be generated in the micro-environment above the general carbonate saturation horizon as a result of intense POC respiration. Therefore, dissolution of the more soluble aragonite could happen in the upper water column, which is not considered in this current study. Generally, profiles of sedimentary calcite content versus water depth exhibit classic CaCO3-depth features (Chung et al., 2003) with high constant values of wtCaCO3% at shallower depths and a systematic decrease below the calcite saturation horizon to reach essentially zero content at deeper depths (Broecker and Peng, 1982).
However, plotting the surficial sedimentary wtCaCO3% versus water depth in the Pacific Ocean gives a data cloud (Supplementary Figure S1). Although the decrease of wtCaCO3% with water depth below ∼3,000 m can be illustrated, the trend is rather unrefined to provide any informative message. The reason is that the dynamic ecology (i.e., CaCO3 export productivity) in the surface of the Pacific Ocean and complexity in the deep ocean (i.e., topography, submarine volcano, and circulation, etc.) bring uncertainties to the sedimentary CaCO3 distribution, which demands sub-grouping of the data to distinguish the influence of such processes.
This current study is therefore carried out in order to understand the underlying mechanism of CaCO3 accumulation in the West Pacific Ocean by re-analyzing compiled surficial sedimentary CaCO3 distribution patterns. Our work provides a quantitative constraint of the geographical variations in sedimentary wtCaCO3% distribution in the West Pacific Ocean, which will help to establish a way to constrain the deep ocean circulation and uncover the role of the West Pacific Ocean in global carbon cycles in the geological past.
Methods and Theoretical Model
The Study Area
The intricate bottom topography (i.e., widely distributed seamounts and guyots) of the West Pacific Ocean results in complicated distributions of different thermohaline currents. The deep water below about 3,500 m in the West Pacific Ocean is dominated by the Lower Circumpolar Deep Water (LCDW), which flows northward along the Chatham Rise in the western South Pacific Ocean (Chiswell et al., 2015) and enters the Central Pacific Ocean through the Samoan Passage, where it bifurcates into western, northern, and eastern branches (Figure 1) (Johnson and Toole, 1993; Kawabe et al., 2003; Kawabe and Fujio, 2010). The Upper Circumpolar Deep Water (UCDW), originated from the Antarctic Circumpolar Current (ACC), is transported by the anticyclonic flow at shallower depths through the South Pacific and ultimately enters the Philippine Sea via the Caroline Basin (Figure 1) (Kawabe et al., 2003). Upwelled LCDW in the Northeast Pacific Ocean is transformed into another upper deep water, the North Pacific Deep Water (NPDW), between 2,000 and 3,500 m, which is modified on its southward route by mixing with UCDW.
FIGURE 1. Map of the study region with black markers representing the locations of sediment cores (triangle—the Northwest Pacific; left triangle—the Philippine Sea; diamond—the Western Equatorial Pacific; circle—the Central Pacific) (see Supplementary Table S1). White, gray, and black arrows show the pathway of the major deep thermohaline currents (e.g., the North Pacific Deep Water (NPDW), the Upper Circumpolar Deep Water (UCDW), and the Lower Circumpolar Deep Water (LCDW)) in the Pacific Ocean (Johnson and Toole, 1993; Kawabe et al., 2003; Fiedler and Talley, 2006; Kawabe and Fujio, 2010). Red rhombus represents major volcanoes and hydrothermal vents in the Pacific Ocean (Beaulieu, 2010; Venzke, 2013).
The LCDW fills the deep ocean below about 3,500 m mainly in the West Pacific Ocean (Supplementary Figure S1), producing a relatively young water mass age (500–700 years) in the Central Pacific Basin and older water mass age in the Caroline, Philippine, and North Pacific basins (700–1,000 years) between 3,500 m and 4,000 m, coinciding with the decreasing carbonate ion ([CO32−]) from the Central Pacific Ocean to the Northwest Pacific Ocean as a result of accumulated respiration of organic matter (Supplementary Figures S2, S4). Ages of the water mass and [CO32−] at a depth between 2,500 m and 3,000 m, where UCDW dominates, show weaker inter-basin contrast, but aging of the water mass (decreasing [CO32−]) from the South to the North can still be found in our study region (Supplementary Figures S3, S4).
Data Preparation
Data used in this study include surficial CaCO3 content in sediments (wtCaCO3%), carbonate ion concentration in the deep ocean ([CO32-]), PIC rain (FB), and non-carbonate flux (FM).
Surficial sedimentary wtCaCO3% data used in this article are compiled from previously published references, with details appended in Supplementary Table S1. Sediment cores from the West Pacific Ocean are separated into four geographic groups (e.g., the Northwest Pacific Ocean, the Philippine Sea, the Western Equatorial Pacific Ocean (including mostly the Caroline Basin), and the Central Pacific Ocean). The topographic complex in the deep ocean (e.g., the Ogasawara–Mariana–Palau Ridges, the Caroline Ridges, the Ontong Java Plateau, and the Mid-Pacific Mountains) sets the boundary between different regions (Figure 1), and measured carbonate chemistry (GLODAPv2.2020; Olsen et al., 2020) and simulated deep water-mass ages by the Norwegian Earth System Model (NorESM; Tjiputra et al., 2013) differ among the four regions (Supplementary Figures S2, S3). Carbonate ion concentration ([CO32-]) data used in this study were calculated from titration alkalinity, total dissolved inorganic carbon, salinity, temperature, and pressure (water depth) data obtained from the Global Ocean Data Analysis Project version 2.2020 database (GLODAPv2.2020; Millero, 1995; Olsen et al., 2020). A basin-wide distribution of the deep sea [CO32−] below 1,000 m is illustrated in Supplementary Figure S4, with average values between 2,000 and 3,000 m for different ocean regions and the in situ variance summarized in Table 1.
TABLE 1. Predicted values of the carbonate saturation depth (CSD), carbonate dissolution rate (k*), and non-carbonate flux (FM) obtained from parameters of PIC flux (FB), [CO32−] (spatial mean value ± standard deviation), and observed carbonate compensation depth (CCD) used in the control run.
Rain (flux) of particulate inorganic carbon (PIC; FB) to the surficial sediment consists mostly settling CaCO3 produced in the surface ocean by marine calcifiers. To calculate the PIC rain, the net primary production was first estimated (Supplementary Figure S5A) using the monthly Moderate Resolution Imaging Spectroradiometer (MODIS) datasets based on a carbon-based production model (CBPM; Behrenfeld et al., 2005), which is then translated into the export flux of particulate organic carbon (POC; Supplementary Figure S5B) using algorithms developed by Laws et al. (2000).The export flux of PIC is then derived based on the PIC:POC export ratio (Sarmiento et al., 2002), and the PIC rain (Table 1) is assigned to be half of the export flux of PIC due to carbonate dissolution in the water column as a result of POC remineralization (Feely et al., 2004). Dilution of marine CaCO3 in the pelagic ocean is largely determined by non-carbonate components, such as lithogenic materials and biogenic opal, despite dominant fluvial input to ocean margins. As the major source for lithogenic input (FM), eolian dust is estimated by various means (Kienast et al., 2016), and the results are shown in Supplementary Table S2. In particular, model simulated dust deposition (Supplementary Figure S6; Jickells et al., 2005) suggests that the Northwest Pacific Ocean has the highest mean dust deposition at about 0.97 g m−2 yr−1, and dust deposition in other areas ranges from ∼0.2 g m−2 yr−1 (the Central Pacific Ocean and the Western Equatorial Pacific Ocean) to ∼0.84 g m−2 yr−1 (the Philippine Sea).
Carbonate Accumulation Model
To better constrain the observed sedimentary wtCaCO3% distribution, a critical depth where CaCO3 turns under-saturated beneath (the carbonate saturation depth; CSD) is first calculated from [CO32−] in the deep ocean between 2,500 m and 3,000 m in different basins, where the sea water turns under-saturated (Supplementary Figure S4), based on empirical relationships established by Boudreau et al. (2010). Another critical depth where the carbonate sedimentation rate balances its dissolution rate (the carbonate compensation depth; CCD) can be determined by finding the depth, below which no accumulation of CaCO3 could be found. Observed locations of CCD can be used to derive values of the dissolution rate of CaCO3 (k*; Table 1) with the PIC rain (FB), deep sea [CO32-], and non-carbonate flux (FM) (Li et al., 2021; Liu et al., 2022).
Ultimately, the sedimentary wtCaCO3% (B) at a given water depth between CSD and CCD can be calculated by:
where ρCaCO3 is the mass density of CaCO3 (2.5 × 104 mol m−3; Boudreau, 2013), ρM is the density of non-carbonate sediment (2.5 × 106 g m3; Archer, 1996), FB is the PIC rain (mol m−2 yr−1), [CO32−] and [CO32−]sat are deep-sea carbonate ion and deep-sea carbonate ion at saturation, respectively, and FM is the non-carbonate flux (g m−2 yr−1), which can be calculated from observed constant sedimentary wtCaCO3% (B) above the CSD (Liu et al., 2022; Supplementary Table S2).
Results
Sedimentary CaCO3 Distributions
Locations of the samples and distributions of sedimentary CaCO3 in different ocean regions are shown in Figure 2. The deposition depth of marine CaCO3 is relatively shallow in the Northwest Pacific Ocean and the Philippine Sea. Pelagic sediments in the Northwest Pacific have 70%–80% wtCaCO3 at ∼2,500 m, below which wtCaCO3% decreases to zero at ∼4,000 m (black triangles in Figures 2A,B). In the pelagic Philippine Sea, sedimentary wtCaCO3% decreases with a water depth from ∼92% at ∼1,600 m, and almost no CaCO3 can be found in sediments at depths below ∼4,100 m (filled black left triangles in Figures 2C,D), with most of sedimentary wtCaCO3% data between 2,000 m and 4,000 m from core-tops retrieved on the Ogasawara–Mariana and Kyushu–Palau ridges (unfilled left triangles in Figures 2C,D). The sedimentary CaCO3 distribution in the Western Equatorial Pacific Ocean (diamonds) and the Central Pacific Ocean (circles) is presented in Figures 2E–H, with sedimentary wtCaCO3% decreasing below ∼3,000 m with depths to reach zero at ∼4,500 m and ∼5,200 m, respectively.
FIGURE 2. Location of the sampling sites and distributions of sedimentary CaCO3 in the Northwest Pacific Ocean [triangles; (A,B)], Philippine Sea [left triangles; (C,D)], Western Equatorial Pacific Ocean [diamonds; (E,F)], and Central Pacific Ocean [circles; (G,H)]. Pelagic sediments with high CaCO3 content presumably not strongly affected by non-carbonate dilution are marked by filled black symbols, while those with low CaCO3 content are marked by unfilled black symbols. Samples from ocean margins with low CaCO3 content are labeled in red [panels (A–D)]. The solid black lines are model outputs (control runs) for the pelagic Northwest Pacific Ocean (A), Philippine Sea (B), Western Equatorial Pacific Ocean (C), and Central Pacific Ocean. The sensitivity tests with [CO32−] (±∼5 μmol kg−1) are presented by the red dashed line.
Model Outputs
Features in observed CaCO3-depth profiles can be largely reproduced by our model using parameters listed in Table 1. The predicted positions of CSD for different regions generally correspond to where the first systematic decrease of sedimentary wtCaCO3% can be observed (Figure 2). The CSD is the deepest in the Central Pacific Ocean (∼2,900 m) with a slight shoaling to ∼2,800 m in the Western Equatorial Pacific Ocean and ∼2,700 m in the Philippine Sea. The CSD is the shallowest (∼2,300 m) in the Northwest Pacific Ocean. Such results are based on measured deep-sea [CO32−] averaged over 300 m above the sea floor for depths between 2,500 m and 3,000 m, obtained from GLODAPv2-2020 data (Supplementary Figure S4; Olsen et al., 2020). The dissolution rate of CaCO3 (k*) calculated based on observed values of CCD is on the same order of magnitude among sediments from different regions of the West Pacific Ocean (Table 1), with a relatively low k* (∼2 m yr−1) for the Central Pacific Ocean, a high k* (∼5 m yr−1) for the Western Equatorial Pacific Ocean, and medium k* (∼3 m yr−1) for other regions.
The predicted CaCO3-depth profiles (solid lines in Figure 2) from our model can reproduce the general patterns of observed sedimentary CaCO3 distribution across different domains, despite some data points deviated from the depth-CaCO3 profiles and uncertainties associated with the sedimentary wtCaCO3% data that will be addressed later. A comparison between the measured wtCaCO3% data and model outputs (control runs) suggests that model simulations are statistically consistent with the actual data (Supplementary Figure S7).
Discussion
Influence of Deep Ventilation on the Sedimentary CaCO3 Distribution
Intrusion of the LCDW and UCDW originated from the Southern Ocean into the Central Pacific Basin results in relatively higher dissolved [CO32−] (∼75 μmol kg−1) below 2,000 m than other regions in the West Pacific Ocean (Supplementary Figures S3, S4). Therefore, the deep water in the Central Pacific Basin is relatively carbonate saturated so that CaCO3 can be better preserved at depths. Aging of the UCDW and a branch of the LCDW that enters the Western Equatorial Pacific Ocean do not integrate enough with effect of POC remineralization with time in the Western Equatorial Pacific Ocean so that the regional deep-sea [CO32-] in the deep Western Equatorial Pacific Ocean (∼74 μmol kg−1) remains close to that in the Central Pacific Ocean. The deep water in the Philippine Sea is largely controlled by the UCDW since direct intrusion of the younger and deeper LCDW is restricted by the island chains, which leads to lower deep-sea [CO32−] (∼71 μmol kg−1) than that in the deep Western Equatorial Pacific Ocean. Further north, weakening of LCDW with a volume transport of 12–14 Sv (106 m3 s−1) in the Central Pacific Ocean to 6 Sv in the Northwest Pacific Ocean (Kawabe and Fujio, 2010), as well as enhanced control of the North Pacific Deep Water (NPDW) in the Northwest Pacific Ocean, is in coincidence with a distinct decline of [CO32−] (∼68 μmol kg−1) compared to other regions and shallow saturation depth of sedimentary CaCO3 (2,420 m; Figure 2; Table 1).
To counteract the increasing TCO2 resulted from accumulated organic matter respiration with time and compensate for the loss of [CO32−], carbonate dissolution takes place at shallower ocean depths as the deep water ages (Figures 2; Supplementary Figure S4). Therefore, the contrasting features of sedimentary CaCO3 between the equatorial regions (e.g., the Western Equatorial Pacific Ocean and the Central Pacific Ocean) and the northwest regions (the Philippine Sea and the Northwest Pacific Ocean) in our study region can be attributed to patterns of the abyssal circulation. Below the carbonate saturation depth, accumulation of CaCO3 in marine sediments is determined by the rate of carbonate dissolution (k*) (Boudreau et al., 2020). The approach we take can help to estimate the basin-scale-averaged carbonate dissolution rate (k*) in the West Pacific Ocean, which seems to be in concert with k* based on water-side control (Table 1; Sulpis et al., 2018), consistent with our previous estimation of k* in the Southwestern Atlantic Ocean and marginal seas in the western Pacific Ocean (Li et al., 2021; Liu et al., 2022). Therefore, our calculation is in support of the assertion that carbonate dissolution is mainly controlled by diffusion through the diffusion boundary layer (Boudreau et al., 2020).
With the lowest k* (∼2 m yr−1) among different regions in the West Pacific Ocean, CaCO3 dissolves slow in under-saturated deep waters in the Central Pacific Ocean so that more CaCO3 can get accumulated in sediment at a deeper depth. In contrast, the high k* (∼5 m yr−1) in the Western Equatorial Pacific Ocean infers fast CaCO3 dissolution, and CaCO3 can get accumulated in sediment at a much shallower depth compared to that in the Central Pacific Ocean, though the PIC rain in the Western Equatorial Pacific Ocean is doubling that in the Central Pacific Ocean. The rate of carbonate dissolution (k*) due to water-side control is determined by the rate of deep current, and our derived high k* in the Western Equatorial Pacific Ocean and low k* in the Central Pacific Ocean are in line with high bottom current speed in the Western Equatorial Pacific Ocean and low bottom current speed in the Central Pacific Ocean (Sulpis et al., 2018).
Influence of Non-Carbonate Dilution
It is worth mentioning that the uncertainty in regional [CO32-] or observed location of CCD cannot fully account for the variability of basinal sedimentary wtCaCO3% distribution (Figures 2, 3). The sedimentary wtCaCO3% above the carbonate saturation depth in both the Western Equatorial Pacific Ocean and the Central Pacific Ocean shows strong regional variability (Figure 3), which could either be caused by different in situ PIC rain (FB) or varied dilution intensity of the non-carbonate flux (FM). The estimated PIC rain (FB; Table 1) in the Western Equatorial Pacific Ocean is more than doubling that in the Central Pacific Ocean. However, the sedimentary wtCaCO3% above the CSD in the Western Equatorial Pacific Ocean is not higher than that in the Central Pacific Ocean, suggesting non-carbonate materials in sediments is playing an important role in determining wtCaCO3%.
FIGURE 3. Pelagic sedimentary wtCaCO3%-depth profiles and model outputs for the Northwest Pacific Ocean (A), Philippine Sea (B), Western Equatorial Pacific Ocean (C), and Central Pacific Ocean (D). Predictions by the model’s control run (Table 1) are shown by bold black lines. The sensitivity tests with observed position of carbonate compensation depth (±400 m, with corresponding uncertainty of the carbonate dissolution rate k*) and non-carbonate fluxes FM (±50%) are presented by green and golden dashed lines, respectively. The carbonate saturation depth (CSD) and carbonate compensation depth (CCD) are indicated by the black dotted and dashed lines, respectively.
Calculated fluxes of non-carbonate materials (FM) are high in the Western Equatorial Pacific Ocean (∼2.4 g m−2 yr−1), which is generally in agreement with the high flux of non-carbonate materials recorded by sediment traps but remarkably higher than simulated dust deposition rates and Th-derived lithogenic flux (Supplementary Figure S6; Supplementary Table S2). Such a comparison indicates that lithogenic input alone is not sufficient to account for the carbonate dilution in the Western Equatorial Pacific Ocean. Alternatively, high fluxes of biogenic opal with spatial disparity in the Western Equatorial Pacific Ocean, and perhaps in the equatorial upwelling region in the Central Pacific Ocean as well, could have contributed to the dilution of CaCO3 in sediment.
Lack of sedimentary wtCaCO3% data above CSD in both the Northwest Pacific Ocean and the Philippine Sea hinders our constraint on the flux of non-carbonate materials in both basins. We thus take the dust deposition rates directly as lithogenic flux (FM) in the model, and our model predictions of depth-profiles of sedimentary wtCaCO3% can reasonably reproduce the scarce sedimentary wtCaCO3% data from the two regions, despite lower sedimentary wtCaCO3% data between 2,000 m and 4,000 m from core-tops retrieved mostly on the Ogasawara–Mariana and Kyushu–Palau ridges (unfilled symbols in Figure 2). It is worth mentioning that Th-derived lithogenic flux in the Northwest Pacific Ocean is 1–4 times higher than the rate of dust deposition (Supplementary Table S2), and such a magnitude of increase of FM suffices to reproduce the low sedimentary wtCaCO3% in the pelagic Northwest Pacific Ocean between 2,500 m and 3,600 m (Figure 4).
FIGURE 4. Map (A) detailing ridges in the West Pacific Ocean and (B) plots of sedimentary wtCaCO3% versus depth in the Philippine Sea and the Northwest Pacific Ocean. Pelagic sediments with high CaCO3 content presumably not strongly affected by non-carbonate dilution are marked by filled black symbols, while those with low CaCO3 content from the Emperor Seamount Chain, the Ogasawara–Mariana Ridge, and Kyushu–Palau Ridge are marked by unfilled black symbols. The solid black lines are model outputs (control runs) for the pelagic Northwest Pacific Ocean (B) and Philippine Sea (C). The black dotted, red dotted, dot and dash, and dashed lines show sensitivity tests with 2, 4, 10, and 40 times of FM, respectively.
Sediment-trap-recorded flux of non-carbonate materials in the Northwest Pacific Ocean is 6–20 times higher than the rate of dust deposition (Supplementary Table S2) due to contribution of biogenic opal (Kawahata et al., 1998). Therefore, the spatial variance in the flux of biogenic opal in the Northwest Pacific Ocean could potentially explain some of the low wtCaCO3% found in sediment on the Emperor Seamount Chain. However, trap-recorded flux in the oligotrophic Philippine Sea is only 1–2 times higher than the dust deposition rate (Supplementary Table S2; Kawahata et al., 1998), and such uncertainty could not explain the diluted sedimentary wtCaCO3% in that region (Figure 4C). To reproduce the low sedimentary wtCaCO3% from the Ogasawara–Mariana and Kyushu–Palau ridges, one needs 2–40 times higher flux of non-carbonate materials than the dust deposition rate, which could only be attributed to detritus derived from volcanic activities in this area.
Conclusion
Patterns of accumulated CaCO3 in sediment in the West Pacific Ocean have been revisited. With a simple carbonate accumulation model applied, factors that could exert influence on the sedimentary CaCO3 distribution have been examined. Notwithstanding uncertainties associated with the factors that must account for variability in sedimentary wtCaCO3%, the deep ventilation (a.k.a. thermohaline currents) substantially shapes the depth-profiles of sedimentary CaCO3 in different regions in the West Pacific domain. Furthermore, the dominant control of carbonate dissolution by diffusion through the diffusion boundary layer is verified using our approach, which is in line with the control of deep ocean ventilation on sedimentary CaCO3 distribution. Enhanced dilution by non-carbonate materials of sedimentary CaCO3 on the topographic complex is uncovered, which can potentially obstruct the dissolution profiles constituted by sedimentary wtCaCO3% in the pelagic ocean. Given that the variation of the non-carbonate flux on the topographic complex can be properly constrained, our results imply that the basinal sedimentary wtCaCO3% distribution has the potential to reflect changes of the carbonate chemistry in the deep ocean (2,500 to 3,000 m) in the past, which could be associated with either changes of the property of UCDW or a mass replacement in the West Pacific Ocean. This information would then help us to dictate possible reorganization of the thermohaline circulation and understand the role the West Pacific Ocean played in global carbon cycles in the geological past.
Data Availability Statement
The original contributions presented in the study are included in the article/Supplementary Material, further inquiries can be directed to the corresponding author.
Author Contributions
YL conceived the study. YL, HC, HZ, and JX carried out data analysis. HZ and JX performed model simulations. YL and HC wrote the original draft. HZ, JX, DQ, QC, and JC participated in reviewing and editing the manuscript. All authors contributed to the final version of the manuscript.
Funding
This research was supported by the National Key Research and Development Program of China (2019YFE0114800), the National Natural Science Foundation of China (41976031 and 41976192), and Innovation Group Project of Southern Marine Science and Engineering Guangdong Laboratory (Zhuhai) (No. 311020005). YL acknowledges the support from the State Key Laboratory of Marine Geology, Tongji University (VF201810, MGK1908), the Key Laboratory of Global Change and Marine-Atmospheric Chemistry, MNR (GCMAC1803), and grant from the Open Foundation of Key Laboratory of Submarine Geosciences, MNR (KLSG1904).
Conflict of Interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s Note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors, and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.
Supplementary Material
The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/feart.2022.857260/full#supplementary-material
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Keywords: surface sediment, overturning circulation, non-carbonate dilution, CaCO3, Western Pacific
Citation: Zhang H, Che H, Xia J, Cheng Q, Qi D, Cao J and Luo Y (2022) Sedimentary CaCO3 Accumulation in the Deep West Pacific Ocean. Front. Earth Sci. 10:857260. doi: 10.3389/feart.2022.857260
Received: 18 January 2022; Accepted: 28 March 2022;
Published: 27 April 2022.
Edited by:
Xiting Liu, Ocean University of China, ChinaCopyright © 2022 Zhang, Che, Xia, Cheng, Qi, Cao and Luo. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Yiming Luo, luoyiming@mail.sysu.edu.cn
†These authors have contributed equally to this work