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ASSESSING THE STRATIGRAPHIC INTEGRITY OF PLANKTIC AND BENTHIC 14C RECORDS IN THE WESTERN PACIFIC FOR Δ14C RECONSTRUCTIONS AT THE LAST GLACIAL TERMINATION

Published online by Cambridge University Press:  19 August 2020

Lowell D Stott*
Affiliation:
Department of Earth Science, University of Southern California, 3651 Trousdale Parkway, Los Angeles, CA90089, USA
*
Corresponding author. Email: [email protected].
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Abstract

There is a growing database of radiocarbon (14C) reconstructions from biogenic carbonate taken from marine sediment cores being used to investigate changing ocean circulation and carbon cycling at the end of the last great ice age. Reported here are 14C results from a marine core taken in the Makassar Straits of the western equatorial Pacific that was intended to test whether there was evidence of geologic carbon release to the ocean during the glacial termination. A thorough investigation of planktic and benthic 14C ages with stable isotopes and CT-scans revealed extensive burrowing in the upper 2 m of the core that displaced younger sediments downward by more than half a meter into the glacial section of the core. The vertical displacement is evident in both planktic and benthic fossils. However, the extent of displacement and the stratigraphic disturbance became evident only after multiple measurements of different species and genera. A CT-scan prior to sampling would be an effective screening tool to avoid sampling problem cores such as this.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Arizona Board of Regents on behalf of the University of Arizona 2020

INTRODUCTION

Considerable effort and expense have been devoted to reconstructions of radiocarbon activity (Δ14C) of biogenic carbonates from marine sediments to evaluate how the global-scale overturning circulation responded to climate changes in the past. This is particularly true for the interval spanning the end of the last glacial maxima and the onset of deglaciation (18–14 kyBP) when the radiocarbon activity of the ocean and atmosphere fell by ~190‰ while the production rate of radiocarbon did not decrease correspondingly (Laj et al. Reference Laj, Kissel, Mazaud, Michel, Muscheler and Beer2002; Hain et al. Reference Hain, Sigman and Haug2014). These contrasting observations led to the term “Mystery Interval” (Broecker and Barker Reference Broecker and Barker2007; Broecker Reference Broecker2009). And when considering how to reconcile these two opposing observations, it initially appeared there were only two plausible explanations, both entailing a change in the residence time of waters within the Ocean. The first hypothesis called upon enhanced bottom water stratification and the isolation of an abyssal water mass that accumulated respired metabolic carbon during glaciations (Toggweiler Reference Toggweiler1999) and then the aged, 14C-depleted abyssal waters were ventilated during the Mystery Interval (Broecker Reference Broecker2009). But after considerable effort, no such isolated abyssal water mass has been documented from glacial age sediment records (Broecker et al. Reference Broecker, Barker, Clark, Hajdas, Bonani and Stott2004; Broecker and Clark Reference Broecker and Clark2010; Hain et al. Reference Hain, Sigman and Haug2011; Keigwin and Lehman Reference Keigwin and Lehman2015; Zhao et al. Reference Zhao, Marchal, Keigwin, Amrhein and Gebbie2018). The second hypothesis calls for an enhanced biological pump during glaciations and an overall slow-down of ocean overturning. This would lead to a net accumulation of respired carbon and longer deep-water residence times during glaciations. Then during deglaciation, as ventilation rates increased, the residence time of deep water decreased (Sigman and Boyle Reference Sigman and Boyle2000; Anderson et al. Reference Anderson, Ali, Bradtmiller, Nielsen, Fleisher, Anderson and Burckle2009, Reference Anderson, Sachs, Fleisher, Allen, Yu, Koutavas and Jaccard2019; Kwon et al. Reference Kwon, Sarmiento, Toggweiler and DeVries2011; Jacobel et al. Reference Jacobel, Anderson, Jaccard, McManus, Pavia and Winckler2019; Menviel et al. Reference Menviel, Spence, Yu, Chamberlain, Matear, Meissner and England2018). This hypothesis makes specific predictions about Δ14C change in the ocean during the deglaciation. It predicts that the Δ14C of deep waters throughout the ocean would increase as older (14C-depleted) waters from the glacial ocean were replaced by younger waters at the onset of deglaciation, (Huiskamp and Meissner Reference Huiskamp and Meissner2012; Menviel et al. Reference Menviel, Spence, Yu, Chamberlain, Matear, Meissner and England2018). This hypothesis also predicts that the δ13C of dissolved inorganic carbon in deep waters would increase as 13C-depleted respired carbon is replaced by better-ventilated waters (Menviel et al. Reference Menviel, Spence, Yu, Chamberlain, Matear, Meissner and England2018).

While these ocean circulation hypotheses continue to be investigated, an alternative hypothesis has been put forth that calls upon release of “old” geologic carbon to the ocean and atmosphere during the late glacial and early deglaciation (Stott and Timmermann Reference Stott and Timmermann2011). Evidence in support of this hypothesis includes large Δ14C excursions during the last deglaciation (Figure 1). These excursions have been identified in each ocean basin (Stott et al. Reference Stott, Southon, Timmermann and Koutavas2009, Reference Stott, Davy, Shao, Coffin, Pecher, Neil, Rose and Bialas2019a, Reference Stott, Davy, Shao, Coffin, Pecher, Neil, Rose and Bialas2019b; Mangini et al. Reference Mangini, Godoy, Godoy, Kowsmann, Santos, Ruckelshausen, Schroeder-Ritzrau and Wacker2010; Stott and Timmermann Reference Stott and Timmermann2011; Ronge et al. Reference Ronge, Tiedemann, Lamy, Kohler, Alloway, De Pol-Holz, Pahnke, Southon and Wacker2016; Rafter et al. Reference Rafter, Herguera and Southon2018). But there are vast portions of the ocean that have not been explored. Hence, it is not yet clear how extensive these deglacial Δ14C excursions were and therefore, how much “old” carbon was released to the oceans during the late glacial and early deglaciation. For this reason, efforts are underway to investigate other locations where geologic carbon may have been released to the oceans, including sites in the western equatorial Pacific, which is a geologically active region with numerous hydrothermal and volcanic sources that could contribute 14C-depleted carbon to the ocean.

Figure 1 Upper panel is a site location map of the MD98-2164 core and other shallow-intermediate depth cores from previous studies that document benthic Δ14C excursions at the last glacial termination (lower panel), Table 2.

In 1998 a coring cruise with the Marion Dufresne set out to obtain a suite of cores in the western Pacific, including sites within the Indonesian Archipelago. The original goal of the endeavor was to investigate the history of the Indonesian Throughflow during the Pleistocene using geochemical tracers to assess whether there was a change in the exchange of waters between the Pacific and Indian Oceans. The exchange of upper ocean waters between the Pacific to the Indian Ocean plays an important role in maintaining continuity in exchange of energy, mass and chemical constituents between ocean basins. For that study a suite of sediment cores was collected from shallow/intermediate water depths between 600 and 1000 m within the Indonesian Archipelago. And because these cores are located in the volcanically active Indonesian region, they are also ideally suited for investigating the history of Δ14C change and the potential role that geologic sources of carbon had on the carbon cycle during the last glacial cycle.

Studies of marine sediments typically begin by developing a stable oxygen isotope stratigraphy from planktic or benthic foraminiferal calcite taken from discrete horizons in a core. The downcore stable isotope values are then compared to well-established marine composite records (standard curves) of planktic or benthic δ18O that have been chronologically aligned to U/Th dated speleothem δ18O records or ice core records (Lisiecki and Stern Reference Lisiecki and Stern2016). But comparing a sediment core’s stable isotope stratigraphy to a standard curve leaves uncertainty about a core’s stratigraphic continuity or integrity. This is because sediment disturbances, missing sediments (hiatuses) may be undetectable from these comparisons alone. Radiocarbon data of biogenic constituents such as foraminifera may be a useful tool for evaluating a core’s stratigraphic integrity. At the same time, these are costly measurements and when the purpose of making the 14C measurements is to explore whether there was a radiocarbon anomaly at the glacial termination, it is also possible that what may appear to be a 14C excursion is in fact, an artifact of core disturbance. This becomes clear only after developing a stable isotope stratigraphy and making numerous 14C measurements. In the present study an example is presented that illustrates how important it is to thoroughly investigate whether the stratigraphy of a core has been disrupted by post depositional processes such as large burrowing, which can displace sediments.

STUDY SITE AND METHODS

In 1998 core MD9821-64 was collected in the Makkassar Strait (Figure 1) (6.64°S, 119.42°E; 719 m water depth). The core was split into two halves. One half was used for sampling, the other archived. Sediment samples were taken at 5-cm intervals. Each sample was disaggregated in a buffered sodium hexametaphosphate solution and then washed over a 63µm screen to remove the fines. The >63µm fraction was then dried at low temperature. After drying the samples were weighed and stored in labeled vials. In April of 2010 a stable isotope stratigraphy was developed for the MD98-2164 core by analyzing samples of ~20 planktic foraminifer Globigerinoides ruber (white) (>250 mm size fraction) picked from samples at 20–40-cm intervals in top two core sections. Prior to analysis the G. ruber samples were sonicated in distilled water for several seconds to remove fine debris and then dried at low temperature. The δ18O and δ13C was measured on a Micromass Isoprime dual inlet mass spectrometer with carbonate device located at the University of Southern California in April 2010. A standard calcite (Ultiss) was measured in the same system along with the foraminiferal samples. Average precision for these standards was <0.15‰ for both oxygen and carbon. All stable isotope results are reported in ‰ relative to VPDB standard. Single specimens of G. ruber and Globigerinoides sacculifer (>250 mm, no final sac) were also analyzed from 4 samples (11 cm, 181 cm, 191 cm and 195 cm). These specimens were cleaned using the same method as the multi-specimen samples. The Ultiss standard was run with these samples at weights similar to that of the single specimens (~20 µg). The precision for these small standard samples was also <0.15‰.

Between December 2009 and July 2010 planktic and benthic foraminifera were picked for radiocarbon analysis to assess whether there were changes in the surface to intermediate depth 14C age difference at the last glacial termination. Similar studies using cores from the eastern equatorial Pacific have documented large benthic-planktic (B-P) 14C age increases at the last glacial termination (Stott et al. Reference Stott, Southon, Timmermann and Koutavas2009). Using the stable isotope stratigraphy as a guide, samples were selected at 10–20-cm intervals, starting from the 3-cm interval down to the δ18O maxima at 199 cm. In some samples the benthic foraminifer Oridorsalis sp were large enough to be analyzed individually. Bivalve shells and Gastropod specimens were also analyzed from several intervals. These samples were cleaned in the same way as the stable isotope samples. After cleaning and weighing the samples were submitted to the Keck Carbon Cycle AMS Laboratory at the University of California Irvine. The 14C ages are summarized in Table 1 in the chronologic order in which they were analyzed.

Table 1 MD9821-64 14C results.

Note: Fossil names followed by (A) or (B) are individual specimen. Fossil names followed by (1) or (2) were replicate, multi-specimen samples. All results have been corrected for isotopic fractionation according to the conventions of Stuiver and Polach (Reference Stuiver and Polach1977), with δ13C values measured on prepared graphite using the AMS spectrometer at UCI.

In August 2010 the top two sections of the core (half round tubes) were passed through a computed tomography scan (CT-scan) that combines X-ray measurements taken at different angles to produce a cross-sectional visualization of the internal structures of the core. This technique visualizes relative differences in sediment density and thus, is useful for characterizing core disturbances created by burrowing organisms.

RESULTS AND DISCUSSION

The initial suite of G. ruber δ18O measurements (Figure 2) document two interglacial to glacial transitions corresponding to marine isotope stages 1 and 2 (0–200 cm) and stages 4 and 5 (750–900 cm). The magnitude of change between the warm interglacial stage 1 and the colder glacial stage 2 is ~2‰ and very close to other G. ruber δ18O records developed from higher deposition rate cores from the western Pacific (Stott et al. Reference Stott, Poulsen, Lund and Thunell2002, Reference Stott, Cannariato, Thunell, Haug, Koutavas and Lund2004, Reference Stott, Timmermann and Thunell2007; Saikku et al. Reference Saikku, Stott and Thunell2009). There is no indication of a break in the glacial to interglacial δ18O stratigraphy except a sample at 141 cm that has a slightly higher δ18O value than the sample at 161 cm. The stable isotope stratigraphy indicates the last glacial maximum occurs at ~199 cm. Using the 199 cm sample as a chronologic datum implies an average sedimentation rate of ~10 cm/kyr for the top 2 m of the core. With these results in hand it appeared appropriate to proceed with the second phase of the study, to develop planktic and benthic 14C ages to investigate whether there was increased benthic-planktic 14C age differences at the glacial termination as seen in other shallow-intermediate depth cores (see Table 2).

Figure 2 Multi-specimen δ18O ‰ values of G. ruber (white) from core MD98-2164.

Table 2 Shallow-intermediate depth sites shown in Figure 1.

An initial suite of 14C measurements was conducted on multi-specimens of the planktic species Globigerinoides sacculifer and the benthic genus Oridorsalis (Figure 3a). This included 4 analyses of individual Oridorsalis sp specimens that were large enough for analysis. The planktic 14C ages appeared to confirm the stratigraphic ages inferred from the G. ruber δ18O stratigraphy. The G. sacculifer 14C age at 199 cm of 19,030 years is consistent with this being the last glacial maximum. At the same time, several observations stood out when comparing the benthic and planktic 14C ages. At the top of the core the B-P 14C ages are 450 and 625 years, close to modern sea water age contrast between the surface and 700–800 m. But the B-P 14C values for the 101 cm and 161 cm samples are reversed (–322 and –635 years, respectively). And even more striking, the B-P 14C age for the multi-specimen samples increase to 6070 years in the 199-cm sample. By contrast, the single specimen Oridorsalis to planktic age difference, is 3410 and 2260 years.

Figure 3 Panel A, the initial batch of 14C ages obtained for G. sacculifer and Oridosalis sp. Note the large age offset between the Oridorsalis and G. sacculifer ages at the 199-cm horizon. Panel B is the second batch of benthic and planktic 14C ages. Note that in the second batch the ages from the 191 cm and 195 cm samples are much younger than the surrounding intervals, including the 199-cm horizon, just 4 cm deeper in the core. Panel C is the all the data plotted together highlighting the anomalously “young” ages of specimens between 191 cm and 195 cm.

These initial results constituted a perplexing problem. The reversal of B-P 14C ages in two intervals might be indicative of a core disturbance and reworking of older material. At the same time, the large increase in B-P 14C ages at 199 cm was an intriguing indication that the core might also record a large benthic 14C excursion at the glacial termination like those seen at other sites (Figure 1). And the fact that the two individual benthic specimens at 199 cm have very different ages compared to the bulk specimen sample was also intriguing. It could mean that there was reworking of older materials into this horizon or, it could mean that there was variable input of local geologic “dead” carbon from nearby sources. For this reason, the next logical step was to evaluate whether the planktic foraminifera also contained mixed ages because planktic 14C ages should not be influenced by localized input of geologic carbon. However, planktic specimens are too small for individual 14C dating. Instead, a suite of planktic G. sacculifer and G. ruber were analyzed individually for δ18O in June of 2010 (Figure 4). The results from these analyses were even more perplexing. Among the individual G. sacculifer δ18O results at 191 cm and 195 cm there are values that are clearly indicative of early and late Holocene δ18O values. This is at odds with the benthic 14C ages at 199 cm that appeared to document much older glacial benthic ages, not younger ages. The stable isotopes and the radiocarbon results seemed to be giving very different results. And further perplexing was the fact that there are no G. ruber δ18O outliers, only the individual G. sacculifer exhibit “younger” outliers (Figure 4).

Figure 4 Upper panel is individual specimen δ18O values for G. ruber. Lower panel is individual δ18O values of G. sacculifer (no final sac). Note that in the 191-cm and 195-cm intervals approximately 10% of the individuals exhibit anomalously “young” δ18O values that are indicative of intervals higher in the core.

By the end of June 2010, a decision had to be made whether to proceed with the investigation. On one hand, the large increase in benthic 14C ages at 199 cm was an intriguing possibility that the core might document “old” carbon at the glacial termination. On the other hand, the fact that the G. sacculifer δ18O results contained what appeared to be “younger” ages in the 195 cm sample suggested that this portion of the core may be compromised in some way. The decision was made to submit a second batch of samples for 14C dating. This time the focus was only on the intervals between 101 and 199 cm. The samples included different species, including some bivalve specimens and a gastropod specimen (Table 1). This second batch also included two separate samples of G. sacculifer from the 191-cm and the 195-cm intervals. In this case G. sacculifer specimens were split into two categories. Category (1) contained only pristine, unbroken tests. Category (2) specimens were less well-preserved, either because the specimens were slightly broken, abraded or dirtier. The reasoning was that perhaps there were two age groups that might be distinguishable based on their degree of preservation. The findings from the second batch are shown in Figure 3B.

The 14C results from the second batch clearly indicate that the interval centered between 190 and 200 cm of the core contains a mixture of specimens with widely varying ages. And importantly, the second batch of G. sacculifer returned ages that were very different from those from the first batch. The G. sacculifer 14C ages from the 191 cm and 195 cm are between 12,000 and 14,000 years and thus, are not glacial values whereas the first batch of G. sacculifer from the 199-cm interval has a 14C age of 19,030 years and is glacial age. And there is no significant age difference between the Category (1) and Category (2) G. sacculifer. Both are anomalously “young”. The Neoglobquadrina dutertrei and G. ruber ages at 191 cm and 195 cm by contrast are much older than G. sacculifer. It is particularly striking that within 4 centimeters, the G. sacculifer 14C ages differ by as much as 7000 years. Furthermore, the bivalve shell and the Gastropod specimen both have late glacial/early deglacial ages and are not as anomalously young as are the G. sacculifer specimens. However, the Oridorsalis samples at 191 cm and 195 cm are much younger (16,900 and 15,120 years respectively) than the glacial age sample at 199 cm.

When all the 14C ages are plotted together (Figure 4C) it becomes evident that the entire core between approximately 60 cm and 200 cm contains a menagerie of mixed 14C ages. And most striking are the anomalously young ages in the 191–199-cm samples, particularly the G. sacculifer and Oridorsalis ages. These results imply that many specimens of G. sacculifer and Oridorsalis have been displaced downward from intervals higher in the sediment column and the displacement is more than 50 cm.

Having invested so much time and financial resources in this core it seemed appropriate to try to determine what process could possibly explain the strange array of radiocarbon ages, particularly the anomalously “young” ages at 191–195 cm. Bioturbation comes in many forms and has varying influences on the sediment mixing. Studies of excess 234Th and 10Be have even documented downward transport in modern sediments of as much as 26 cm (Smith et al. Reference Smith, Berelson, Demaster, Dobbs, Hammond, Hoover, Pope and Stephens1997). But the radiocarbon results from the MD98-2164 core seem to imply that downward sediment transport exceeds more than half a meter. To evaluate whether downward burrowing might account for the anomalously “young” ages in the glacial section of the core, a CT-scan was performed on the core. The CT scans does indeed illustrate extensive burrows below 60 cm (Figure 5). In closeup view of the interval between 60 cm and 110 cm the burrows are very large. Some burrows are more than 2 cm in diameter and are lengthy (Figure 6). Single burrows can be traced in multilayer images (not shown) over 30–40 cm. It is therefore evident that at this location, benthic organisms have effectively corrupted the stratigraphic integrity of the core.

Figure 5 False color images of the CT-scans of the top two sections of core MD98-21064. The largest and most evident single burrows are evident between approximately 60 and 120 cm.

Figure 6 CT-scan zoomed in on the interval of section 1 with the largest and longest burrows. The largest burrows are over 2 cm in diameter and can be traced in the CT-scan for over 40 cm.

FINAL THOUGHTS AND CONCLUSIONS

The results from this study highlight several lessons. The first is that if this study had ended after the first batch of 14C ages were obtained, the conclusions might have been completely different. The initial planktic 14C ages did not reveal anything unusual in the stratigraphy. And, the large B-P 14C age increase at 199 cm might have been mistaken for evidence of local input of “old” carbon. But after conducting the stable isotope measurements of single G. sacculifer specimens, it became clear that additional radiocarbon measurements were necessary to better characterize the 14C record of this core. Secondly, had G. ruber been chosen for 14C age dating instead of G. sacculifer, the results may also have been different. For reasons that are not immediately obvious the single specimen δ18O analyses and the 14C ages for G. ruber do not exhibit the same anomalously “young” values at 191–195 cm as do the G. sacculifer values. This is an issue that will require additional investigation. The lesson is that obtaining 14C ages for multiple species of foraminifera is important. This is not always possible where individual benthic foraminifer species are not abundant enough for single species analyses. In the western equatorial Pacific multispecies analyses and replicating observations from multiple closely associated cores proved valuable in validating the extremely 14C-depleted benthic foraminiferal records in the shallow-intermediate water depth cores at that location (Stott et al. Reference Stott, Harazin and Quintana Krupinski2019b). But it is clear that individual data points and even individual core records must be considered with some caution until more comprehensive records become available.

In the MD98-2164 core both benthic and planktic specimens have been displaced downward by as much as 50–60 cm. Presumably, burrowing could also move older sediments upward as well, which would produce what appears to be a Δ14C excursion like those seen in other cores. But burrowing moves both benthic and planktic specimens together, although not necessarily in the same proportion (e.g. G. ruber vs. G. sacculifer). Therefore, measuring multiple species or genera of both planktic and benthic fossils is an important way to distinguish between vertical displacement and what may be inputs of anomalously old carbon. And finally, CT-scans are a valuable and relatively inexpensive method for evaluating the integrity of a core. Had the CT-scans been conducted on the MD98-2164 core before sampling commenced the core would never have been sampled and a great deal of effort and expense would have been avoided. Unfortunately, CT scans may not be practical when sampling old cores that have dried and been heavily sampled.

ACKNOWLEDGMENTS

Appreciation is extended to two anonymous reviewers. This research would not have been possible without the support of the United States National Science Foundation (OCE MG&G 1904433 and 1558990). Special appreciation is extended to Dr. John Southon of the University of California, Irvine AMS facility whose sustained support has made this research endeavor possible.

References

REFERENCES

Anderson, RF, Ali, S, Bradtmiller, LI, Nielsen, SHH, Fleisher, MQ, Anderson, BE, Burckle, LH. 2009. Wind-driven upwelling in the Southern Ocean and the deglacial rise in atmospheric CO2 . Science 323(5920):14431448.CrossRefGoogle ScholarPubMed
Anderson, RF, Sachs, JP, Fleisher, MQ, Allen, KA, Yu, J, Koutavas, A, Jaccard, SL. 2019. Deep-sea oxygen depletion and ocean carbon sequestration during the Last Ice Age. Global Biogeochemical Cycles 33(3):301317.CrossRefGoogle Scholar
Broecker, W. 2009. The mysterious 14C decline. Radiocarbon 51(1):109119.CrossRefGoogle Scholar
Broecker, W, Barker, S. 2007. A 190‰ drop in atmosphere’s Δ14C during the “Mystery Interval” (17.5 to 14.5 kyr). Earth and Planetary Science Letters 256(1–2):9099.CrossRefGoogle Scholar
Broecker, W, Barker, S, Clark, E, Hajdas, I, Bonani, G, Stott, L. 2004. Ventilation of the Glacial Deep Pacific Ocean. Science 306:11691172.CrossRefGoogle ScholarPubMed
Broecker, W, Clark, E. 2010. Search for a glacial-age 14C-depleted ocean reservoir. Geophys. Res. Lett. 37(13):L13606.CrossRefGoogle Scholar
Bryan, SP, Marchitto, TM, Lehman, SJ. 2010. The release of 14C-depleted carbon from the deep ocean during the last deglaciation: evidence from the Arabian Sea. Earth and Planetary Science Letters 298(1–2):244254.CrossRefGoogle Scholar
Hain, MP, Sigman, DM, Haug, GH. 2011. Shortcomings of the isolated abyssal reservoir model for deglacial radiocarbon changes in the mid-depth Indo-Pacific Ocean. Geophysical Research Letters 38(4).CrossRefGoogle Scholar
Hain, MP, Sigman, DM, Haug, GH. 2014. Distinct roles of the Southern Ocean and North Atlantic in the deglacial atmospheric radiocarbon decline. Earth and Planetary Science Letters 394:198208.CrossRefGoogle Scholar
Huiskamp, WN, Meissner, KJ. 2012. Oceanic carbon and water masses during the Mystery Interval: A model-data comparison study. Paleoceanography 27(4):PA4206.CrossRefGoogle Scholar
Jacobel, AW, Anderson, RF, Jaccard, SL, McManus, JF, Pavia, FJ, Winckler, G. 2019. Deep Pacific storage of respired carbon during the last ice age: Perspectives from bottom water oxygen reconstructions. Quaternary Science Reviews:106065.Google Scholar
Keigwin, LD, Lehman, SJ. 2015. Radiocarbon evidence for a possible abyssal front near 3.1 km in the glacial equatorial Pacific Ocean. Earth and Planetary Science Letters 425:93104.CrossRefGoogle Scholar
Kwon, EY, Sarmiento, JL, Toggweiler, JR, DeVries, T. 2011. The control of atmospheric pCO2 by ocean ventilation change: The effect of the oceanic storage of biogenic carbon. Global Biogeochemical Cycles 25(3).CrossRefGoogle Scholar
Laj, C, Kissel, C, Mazaud, A, Michel, E, Muscheler, R, Beer, J. 2002. Geomagnetic field intensity, North Atlantic Deep Water circulation and atmospheric Δ14C during the last 50 kyr. Earth and Planetary Science Letters 200(1):177190.CrossRefGoogle Scholar
Lisiecki, LE, Stern, JV. 2016. Regional and global benthic δ18O stacks for the last glacial cycle. Paleoceanography 31(10):13681394.CrossRefGoogle Scholar
Mangini, A, Godoy, JM, Godoy, ML, Kowsmann, R, Santos, GM, Ruckelshausen, M, Schroeder-Ritzrau, A, Wacker, L. 2010. Deep sea corals off Brazil verify a poorly ventilated Southern Pacific Ocean during H2, H1 and the Younger Dryas. Earth and Planetary Science Letters 293(3):269276.CrossRefGoogle Scholar
Marchitto, TM, Lehman, SJ, Ortiz, JD, Fluckiger, J, van Geen, A. 2007. Marine radiocarbon evidence for the mechanism of deglacial atmospheric CO2 rise. Science 316(5830):14561459.CrossRefGoogle ScholarPubMed
Menviel, L, Spence, P, Yu, J, Chamberlain, MA, Matear, RJ, Meissner, KJ, England, MH. 2018. Southern Hemisphere westerlies as a driver of the early deglacial atmospheric CO2 rise. Nature Communications 9(1):2503.CrossRefGoogle ScholarPubMed
Rafter, PA, Herguera, J-C, Southon, JR. 2018. Extreme lowering of deglacial seawater radiocarbon recorded by both epifaunal and infaunal benthic foraminifera in a wood-dated sediment core. Climate of the Past 14:1977.CrossRefGoogle Scholar
Ronge, TA, Tiedemann, R, Lamy, F, Kohler, P, Alloway, BV, De Pol-Holz, R, Pahnke, K, Southon, J, Wacker, L. 2016. Radiocarbon constraints on the extent and evolution of the South Pacific glacial carbon pool. Nature Communications 7.Google ScholarPubMed
Saikku, R, Stott, L, Thunell, R. 2009. A bi-polar signal recorded in the western tropical Pacific: Northern and Southern Hemisphere climate records from the Pacific warm pool during the last Ice Age. Quaternary Science Reviews 28(23–24):23742385.CrossRefGoogle Scholar
Sigman, DM, Boyle, EA. 2000. Glacial/interglacial variations in atmospheric carbon dioxide. Nature 407:859869.CrossRefGoogle ScholarPubMed
Smith, CR, Berelson, W, Demaster, DJ, Dobbs, FC, Hammond, D, Hoover, DJ, Pope, RH, Stephens, M. 1997. Latitudinal variations in benthic processes in the abyssal equatorial Pacific: control by biogenic particle flux. Deep Sea Research Part II: Topical Studies in Oceanography 44(9):22952317.CrossRefGoogle Scholar
Stott, L, Poulsen, C, Lund, S, Thunell, R. 2002. Super ENSO and global climate oscillations at millennial time scales. Science 297(5579):222226.CrossRefGoogle ScholarPubMed
Stott, L, Cannariato, K, Thunell, R, Haug, GH, Koutavas, A, Lund, S. 2004. Decline of surface temperature and salinity in the western tropical Pacific Ocean in the Holocene epoch. Nature 431:5659.CrossRefGoogle ScholarPubMed
Stott, L, Timmermann, A, Thunell, R. 2007. Southern hemisphere and deep-sea warming led deglacial atmospheric CO2 rise and tropical warming. Science 318(5849):435438.CrossRefGoogle ScholarPubMed
Stott, L, Southon, J, Timmermann, A, Koutavas, A. 2009. Radiocarbon age anomaly at intermediate water depth in the Pacific Ocean during the last deglaciation. Paleoceanography 24.Google Scholar
Stott, L, Timmermann, A. 2011. Hypothesized link between glacial/interglacial atmospheric CO2 cycles and storage/release CO2-rich fluids from the deep sea. Geophysical Monograph Series: Understanding the Causes, Mechanisms and Extent of the Abrupt Climate Change.: American Geophysical Union.CrossRefGoogle Scholar
Stott, LD, Davy, B, Shao, J, Coffin, R, Pecher, I, Neil, H, Rose, P, Bialas, J. 2019a. CO2 release from pockmarks on the Chatham Rise-Bounty trough at the glacial termination. Paleoceanography/Paleoclimatology 34.CrossRefGoogle Scholar
Stott, LD, Harazin, KM, Quintana Krupinski, NB. 2019b. Hydrothermal carbon release to the ocean and atmosphere from the eastern equatorial Pacific during the last glacial termination. Environmental Research Letters 14(2):025007.CrossRefGoogle Scholar
Stuiver, M, Polach, HA. 1977. Discussion reporting of 14C data. Radiocarbon 19(3):355363.CrossRefGoogle Scholar
Toggweiler, JR. 1999. Variation of atmospheric CO2 by ventilation of the ocean’s deepest water. Paleoceanography 14(5):571588.CrossRefGoogle Scholar
Zhao, N, Marchal, O, Keigwin, L, Amrhein, D, Gebbie, G. 2018. A synthesis of deglacial deep-sea radiocarbon records and their (in)consistency with modern ocean ventilation. Paleoceanography and Paleoclimatology 33(2):128151.CrossRefGoogle Scholar
Figure 0

Figure 1 Upper panel is a site location map of the MD98-2164 core and other shallow-intermediate depth cores from previous studies that document benthic Δ14C excursions at the last glacial termination (lower panel), Table 2.

Figure 1

Table 1 MD9821-64 14C results.

Figure 2

Figure 2 Multi-specimen δ18O ‰ values of G. ruber (white) from core MD98-2164.

Figure 3

Table 2 Shallow-intermediate depth sites shown in Figure 1.

Figure 4

Figure 3 Panel A, the initial batch of 14C ages obtained for G. sacculifer and Oridosalis sp. Note the large age offset between the Oridorsalis and G. sacculifer ages at the 199-cm horizon. Panel B is the second batch of benthic and planktic 14C ages. Note that in the second batch the ages from the 191 cm and 195 cm samples are much younger than the surrounding intervals, including the 199-cm horizon, just 4 cm deeper in the core. Panel C is the all the data plotted together highlighting the anomalously “young” ages of specimens between 191 cm and 195 cm.

Figure 5

Figure 4 Upper panel is individual specimen δ18O values for G. ruber. Lower panel is individual δ18O values of G. sacculifer (no final sac). Note that in the 191-cm and 195-cm intervals approximately 10% of the individuals exhibit anomalously “young” δ18O values that are indicative of intervals higher in the core.

Figure 6

Figure 5 False color images of the CT-scans of the top two sections of core MD98-21064. The largest and most evident single burrows are evident between approximately 60 and 120 cm.

Figure 7

Figure 6 CT-scan zoomed in on the interval of section 1 with the largest and longest burrows. The largest burrows are over 2 cm in diameter and can be traced in the CT-scan for over 40 cm.