Productivity patterns in the equatorial Pacific over the last 30,000 years

Global Biogeochemical Cycles

Sachs

Fleisher

et al. 2019

Self Cite

Enhanced ocean carbon storage during the Pleistocene ice ages lowered atmospheric CO2 concentrations by 80 to 100 ppm relative to interglacial levels. Leading hypotheses to explain this phenomenon invoke a greater efficiency of the ocean's biological pump, in which case carbon storage in the deep sea would have been accompanied by a corresponding reduction in dissolved oxygen. We exploit the sensitivity of organic matter preservation in marine sediments to bottom water oxygen concentration to constrain the level of dissolved oxygen in the deep central equatorial Pacific Ocean during the last glacial period (18,000–28,000 years BP) to have been within the range of 20–50 μmol/kg, much less than the modern value of ~168 μmol/kg. We further demonstrate that reduced oxygen levels characterized the water column below a depth of ~1,000 m. Converting the ice age oxygen level to an equivalent concentration of respiratory CO2, and extrapolating globally, we estimate that deep‐sea CO2 storage during the last ice age exceeded modern values by as much as 850 Pg C, sufficient to balance the loss of carbon from the atmosphere (~200 Pg C) and from the terrestrial biosphere (~300–600 Pg C). In addition, recognizing the enhanced preservation of organic matter in ice age sediments of the deep Pacific Ocean helps reconcile previously unexplained inconsistencies among different geochemical and micropaleontological proxy records used to assess past changes in biological productivity of the ocean.

Section: Resultssupporting

confidence: 88%

Section: Discussionsupporting

confidence: 78%

Deep‐Sea Oxygen Depletion and Ocean Carbon Sequestration During the Last Ice Age

Global Biogeochemical Cycles

Sachs

Fleisher

et al. 2019

Self Cite

“…Along the equatorial Pacific, Holocene mass fluxes average about 1 g/cm 2 kyr, with a latitudinal gradient that mirrors the decreasing productivity trend with increasing distance from the nutrient‐rich zone of equatorial upwelling. For example, at the Line Islands (approximately −160°E), Holocene mass fluxes along a latitudinal transect of nine sites steadily decrease from ~1.8 g/cm 2 kyr at the equator (0.2°S) to 0.8 g/cm 2 kyr at the northernmost site (7.0°N) (Costa et al, , ; Jacobel et al, ), a trend that is not captured in age model‐based mass accumulation rates. The equatorial Pacific also manifests a distinct zonal distance effect (supporting information Figure S6), with the lowest mass fluxes occurring in the central equatorial Pacific (~0.5 g/cm 2 kyr) and increasing more or less monotonically toward the continental margins.…”

Section: Th Global Database Resultsmentioning

confidence: 99%

“…This situation creates a concentration gradient in the water column that in turn generates a dispersive transport (advection + eddy diffusion) of the affected element toward the high‐particle‐flux zone, a process called boundary scavenging, as it was first identified at continental boundaries (Bacon et al, ). Boundaries are now defined more broadly, and they can include productivity gradients such as those driven by upwelling in the central equatorial Pacific (e.g., Costa et al, ), which can occur far from any continental margin.…”

Section: Uncertainties and Limits Of The Constant 230th Flux Modelmentioning

confidence: 99%

²³⁰Th Normalization: New Insights on an Essential Tool for Quantifying Sedimentary Fluxes in the Modern and Quaternary Ocean

Costa

Hayes

Paleoceanog and Paleoclimatol

et al. 2020

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230Th normalization is a valuable paleoceanographic tool for reconstructing high‐resolution sediment fluxes during the late Pleistocene (last ~500,000 years). As its application has expanded to ever more diverse marine environments, the nuances of 230Th systematics, with regard to particle type, particle size, lateral advective/diffusive redistribution, and other processes, have emerged. We synthesized over 1000 sedimentary records of 230Th from across the global ocean at two time slices, the late Holocene (0–5,000 years ago, or 0–5 ka) and the Last Glacial Maximum (18.5–23.5 ka), and investigated the spatial structure of 230Th‐normalized mass fluxes. On a global scale, sedimentary mass fluxes were significantly higher during the Last Glacial Maximum (1.79–2.17 g/cm2kyr, 95% confidence) relative to the Holocene (1.48–1.68 g/cm2kyr, 95% confidence). We then examined the potential confounding influences of boundary scavenging, nepheloid layers, hydrothermal scavenging, size‐dependent sediment fractionation, and carbonate dissolution on the efficacy of 230Th as a constant flux proxy. Anomalous 230Th behavior is sometimes observed proximal to hydrothermal ridges and in continental margins where high particle fluxes and steep continental slopes can lead to the combined effects of boundary scavenging and nepheloid interference. Notwithstanding these limitations, we found that 230Th normalization is a robust tool for determining sediment mass accumulation rates in the majority of pelagic marine settings (>1,000 m water depth).

“…In this study, we generate new records of productivity ( 231 Pa/ 230 Th, opal flux, and excess silica flux) from the East Subarctic Pacific (approximately 45°N, 230°E, 2,700 m) over the last two glacial cycles. Disagreement between various productivity proxies is not uncommon and may lead to ambiguous paleo‐productivity trends (e.g., in the equatorial Pacific; Anderson & Winckler, ; Costa et al, ), and in the Subarctic (Costa et al, ; Serno et al, ). Because 231 Pa/ 230 Th is the productivity proxy least susceptible to preservation biases, it may provide the most reliable reconstruction of paleoproductivity while allowing the qualitative assessment of the impact of preservation and diagenesis on other proxies, particularly opal, in the Subarctic Pacific.…”

Section: Introductionmentioning

confidence: 99%

Paleoproductivity and Stratification Across the Subarctic Pacific Over Glacial‐Interglacial Cycles

Costa

McManus

Paleoceanog and Paleoclimatol

2018

Self Cite

In the Subarctic Pacific, variability in productivity on glacial‐interglacial timescales is often attributed to changes in stratification and nutrient delivery to the surface, but the mechanisms driving this relationship are poorly constrained. Records extending beyond the last glacial maximum from both the open ocean and the marginal seas are required to investigate the timing and magnitude of different influential processes through the full glacial cycle. In this study we generated 231Pa/230Th over 210,000 years in order to capture two full glacial cycles of paleoproductivity on the Juan de Fuca Ridge in the East Subarctic Pacific. The sedimentary 231Pa/230Th ratios are always equal to or greater than the seawater production ratio (0.093), consistent with enhanced biological scavenging in this region. The temporal pattern of 231Pa/230Th burial is remarkably coherent with changes in climate, with high values (0.20) during peak interglacial periods descending to low values (0.10) during peak glacial conditions, consistent with other long productivity records from this region. We investigate the possible contributions of temperature, sea ice formation, Bering Strait closure, wind strength, upwelling, and subsurface nutrient concentrations as possible mechanisms by which physical and/or chemical stratification emerged during glacial periods. Due to the low sea surface salinity in the North Pacific, cooling actually weakens the density gradient in surface (0–200 m) waters. To create the steep density profiles that characterize physical stratification, additional processes to reduce the salinity of surface waters must occur during glacial periods. We suggest that regional sea ice formation and Bering Strait closure may have contributed to freshening surface waters and enhancing physical stratification during glacial periods. Additionally, simulated weak winds in this region due to the southward shift of the glacial westerlies may have further reduced surface mixing depths in the Subarctic Pacific. Finally, previous model simulations suggest strong glacial wind stress curl in the Subarctic Pacific, but enhanced Ekman divergence of nutrient‐poor subsurface waters would have little impact on stimulating productivity in surface waters of the Subarctic Pacific. We therefore suggest that the combined effects of surface freshening, weak winds, and lower subsurface nutrient concentrations may all have contributed to lower productivity during glacial periods in the Subarctic Pacific.