Changes in Deep‐Sea Oxygenation in the Northeast Pacific Ocean During 32–10 ka

Saravanan, Ponnusamy; Gupta, Anil K.; Zheng, Hongbo; Santosh, K.; Panigrahi, M. K.

doi:10.1029/2019gl086613

Cited by 8 publications

(3 citation statements)

References 49 publications

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“…Given persistent low O2 conditions in the Cascadian Ridge region since 32,000 years ago (cf. Saravanan et al, 2020),…”

Section: Surface and Near Surface Marine Sedimentsmentioning

confidence: 99%

Methylation index of Overly Branched tetraether lipids (MOB): a proxy for deep ocean (de)oxygenation?

Rattanasriampaipong,

Zhang,

Alo

et al. 2024

Preprint

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Branched glycerol dialkyl glycerol tetraethers (brGDGTs) with lower (sparsely-branched; SB-) and higher (overly-branched; OB-) numbers of methylated branches relative to the “regular” brGDGTs (B-GDGTs) are abundant in anoxic waters in the Black Sea. Observed changes in abundances and numbers of methylated branches of the entire series OB-GDGTs, B-GDGTs, and SB-GDGTs relative to dissolved oxygen (DO) levels in anoxic waters suggest that these compounds can potentially track changes in oceanic DO levels through time. To explore this, we determine the entire brGDGT series in surface or near-surface sediments from sites with different DO distributions in marine waters and sediments, extending the limited core-top collection of these lipids. We propose a modified methylation index based on only OB-GDGTs, called MOB, to avoid the potential impacts of terrestrial-derived B-GDGTs. Interestingly, MOB values in our extended core-top collection are strongly related to changes in bottom-water DO concentrations rather than the site-specific minimum DO values, i.e. usually within mid-depth oxygen minimum zones (OMZs). This suggests that sedimentary lipids are likely derived from heterotrophic bacteria living at the sediment-water boundary in sediments while lipids produced within mid-depth OMZs are not effectively exported to deep oceans. Analysis of MOB values in ancient sediments in the East Equatorial Pacific shows a gradual decline in bottom water DO, correlating with the progressive increase in global export productivity, organic carbon burial, and elevated level of deep-water nutrient contents since the middle Miocene. These findings highlight the potential of MOB as a tool for reconstructing past oceanic (de)oxygenation events.

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“…Given persistent low O2 conditions in the Cascadian Ridge region since 32,000 years ago (cf. Saravanan et al, 2020),…”

Section: Surface and Near Surface Marine Sedimentsmentioning

confidence: 99%

Methylation index of Overly Branched tetraether lipids (MOB): a proxy for deep ocean (de)oxygenation?

Rattanasriampaipong,

Zhang,

Alo

et al. 2024

Preprint

View full text Add to dashboard Cite

show abstract

“…At ODP Site 1017, on the slope near Point Conception on the California margin, local productivity may have driven pore-water deoxygenation during the Bølling whereas incursion of low-oxygen intermediate waters may have contributed to dysoxia during the Allerød (Taylor et al, 2017). OMZ intensification on the Cascadia Margin also occurred during the B/A following a dramatic increase in primary productivity related to intense upwelling driven by changes in the California Undercurrent (McKay et al, 2005;Saravanan et al, 2020). High productivity has also been reported during the B/A in the Bering Sea and during the Allerød in the Okhotsk Sea (Max et al, 2014 NPIW extends to the eastern parts of the North Pacific and low-oxygen conditions in Okhotsk Sea Intermediate Water (OSIW) influence the GoA and the eastern North Pacific margin (Max et al, 2014;.…”

Section: Low-oxygen Events In Mis 2 To the Holocenementioning

confidence: 99%

Reconstructing Paleo‐oxygenation for the Last 54,000 Years in the Gulf of Alaska Using Cross‐validated Benthic Foraminiferal and Geochemical Records

sharon

Belanger

et al. 2021

Paleoceanog and Paleoclimatol

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“…North Pacific paleoceanographic records document increases in OMZ extent and intensification, particularly during the Bolling‐Allerod (B/A) and early Holocene, which correspond to intervals of abrupt warming (Belanger et al., 2020; Cannariato & Kennett, 1999; Davies et al., 2011; Jaccard & Galbraith, 2012; Moffitt et al., 2015; Ohkushi et al., 2013; Praetorius et al., 2015; Saravanan et al., 2020; Sharon et al., 2021; Shibahara et al., 2007; Zou et al., 2020). Proposed drivers of these low‐oxygen events include enhanced productivity and respiration of organic carbon at intermediate depths (Davies et al., 2011; Gray et al., 2018; Preatorius et al., 2015, 2020), which would not only reduce dissolved oxygen content, but could also promote dissolution via the production of carbonic acid during respiration (de Villiers, 2005; Boudreau & Canfield, 1993).…”

Section: Introductionmentioning

confidence: 99%

Enhanced Carbonate Dissolution Associated With Deglacial Dysoxic Events in the Subpolar North Pacific

Payne

Belanger

2021

Paleoceanog and Paleoclimatol

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Introduction Oxygen Minimum and Carbonate Maximum Zones in the PacificOxygen minimum zones (OMZs) are regions at intermediate ocean depths with low dissolved oxygen content, the extent of which vary over time with ocean circulation, nutrient availability, and climate (Deutsch et al., 2011;Helly & Levin, 2004;Keeling et al., 2010). These zones are forecast to expand and intensify with ongoing global climate change driven by rising anthropogenic CO 2 (Keeling et al., 2010;Long et al., 2016;Stramma et al., 2008). OMZs also correspond with maxima in dissolved inorganic carbon (DIC), forming corresponding carbon maximum zones (CMZs), due to high-organic carbon respiration and, potentially, enhanced carbonate dissolution driven by that respiration (Paulmier et al., 2011;Wyrtki, 1962). In addition, prolonged hypoxic to anoxic conditions may amplify the effects of benthic respiration on bottom water pH and carbonate saturation (Ω), further enhancing carbonate dissolution in OMZ sediments as they do in coastal environments (Hu et al., 2017;Wang et al., 2020). As a result of these processes, OMZs are presently the primary carbon reservoir of the subsurface ocean and can be sites of CO 2 transfer from the ocean to the atmosphere with significant consequences for oceanic carbon storage and global climates (Naik et al., 2014;Paulmier et al., 2011). Examining the relationship between past intensification of OMZs and changes in marine calcification and carbonate dissolution is important for parameterizing changes in the inorganic carbon cycle that may occur with climate change.The Pacific Ocean contains the world's largest OMZ (Paulmier & Ruiz-Pino, 2009). Oxygen content has decreased and the upper OMZ boundary has shoaled in this region since at least the 1960s in response to warming-induced declines in solubility, enhanced upper ocean stratification, reduced ventilation, and decreased North Pacific Intermediate Water (NPIW) formation (

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Changes in Deep‐Sea Oxygenation in the Northeast Pacific Ocean During 32–10 ka

Cited by 8 publications

References 49 publications

Methylation index of Overly Branched tetraether lipids (MOB): a proxy for deep ocean (de)oxygenation?

Methylation index of Overly Branched tetraether lipids (MOB): a proxy for deep ocean (de)oxygenation?

Reconstructing Paleo‐oxygenation for the Last 54,000 Years in the Gulf of Alaska Using Cross‐validated Benthic Foraminiferal and Geochemical Records

Enhanced Carbonate Dissolution Associated With Deglacial Dysoxic Events in the Subpolar North Pacific

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