A determination of air-sea gas exchange and upper ocean biological production from five noble gases and tritiugenic helium-3

Stanley, Rachel H. R.

doi:10.1575/1912/2029

Cited by 5 publications

(6 citation statements)

References 119 publications

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“…These uncertainties account both for BATS sample measurement uncertainties and uncertainties in the solubility equilibrium ratios. We find remarkably close agreement between our deep BATS Δ(Xe/Ar) and Δ(Kr/Ar) measurements and previous measurements from the early 2000s ( 24 , 25 ), adding confidence to these data ( SI Appendix , Fig. S1 and Fig.…”

Section: Resultssupporting

confidence: 87%

Dissolved gases in the deep North Atlantic track ocean ventilation processes

Seltzer

Nicholson

Smethie

et al. 2023

Proc. Natl. Acad. Sci. U.S.A.

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Gas exchange between the atmosphere and ocean interior profoundly impacts global climate and biogeochemistry. However, our understanding of the relevant physical processes remains limited by a scarcity of direct observations. Dissolved noble gases in the deep ocean are powerful tracers of physical air-sea interaction due to their chemical and biological inertness, yet their isotope ratios have remained underexplored. Here, we present high-precision noble gas isotope and elemental ratios from the deep North Atlantic (~32°N, 64°W) to evaluate gas exchange parameterizations using an ocean circulation model. The unprecedented precision of these data reveal deep-ocean undersaturation of heavy noble gases and isotopes resulting from cooling-driven air-to-sea gas transport associated with deep convection in the northern high latitudes. Our data also imply an underappreciated and large role for bubble-mediated gas exchange in the global air-sea transfer of sparingly soluble gases, including O 2 , N 2 , and SF 6 . Using noble gases to validate the physical representation of air-sea gas exchange in a model also provides a unique opportunity to distinguish physical from biogeochemical signals. As a case study, we compare dissolved N 2 /Ar measurements in the deep North Atlantic to physics-only model predictions, revealing excess N 2 from benthic denitrification in older deep waters (below 2.9 km). These data indicate that the rate of fixed N removal in the deep Northeastern Atlantic is at least three times higher than the global deep-ocean mean, suggesting tight coupling with organic carbon export and raising potential future implications for the marine N cycle.

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Section: Resultssupporting

confidence: 87%

Dissolved gases in the deep North Atlantic track ocean ventilation processes

Seltzer

Nicholson

Smethie

et al. 2023

Proc. Natl. Acad. Sci. U.S.A.

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“…By measuring oxygen and an inert gas simultaneously it is possible to isolate the physical processes causing O 2 change in the upper ocean. It has long been realized that the noble gas argon is ideal for this purpose because it has a similar solubility to oxygen [ Benson , 1964] and the O 2 –Ar pair have been used over the years [e.g., Craig and Hayward , 1987; Spitzer and Jenkins , 1989; Emerson et al , 1995; Kaiser et al , 2005; Hamme and Emerson , 2006; Reuer et al , 2007; Juranek , 2007; Stanley , 2007]. Our goal is to demonstrate the utility of simultaneous measurements of oxygen and nitrogen gases to separate the physical and biological processes causing oxygen change because it is presently possible to measure these two in situ and remotely, which is not yet the case for argon.…”

Section: Discussionmentioning

confidence: 99%

“…Thus it is important to be able to determine the relative importance of the two mechanisms. Gas exchange studies using a suite of inert gases at the Hawaii and Bermuda time series sites [ Hamme and Emerson , 2006; Stanley , 2007] indicate that these two mechanisms are of similar importance with total collapse being responsible for more than half of bubble processes. Since we are dealing with only one inert gas, N 2 , we have to guess about the relative importance of these mechanisms, and that introduces an element of uncertainty in calculation of the effect bubble fluxes on O 2 concentration.…”

Section: Discussionmentioning

confidence: 99%

Net biological oxygen production in the ocean: Remote in situ measurements of O₂ and N₂ in surface waters

Emerson

Stump

Nicholson

2008

Global Biogeochemical Cycles

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[1] We describe a method for determining net annual biological oxygen production in the euphotic zone of the ocean using remote in situ measurements of oxygen and nitrogen gas. Temperature, salinity, oxygen, and total dissolved gas pressure were measured every 2 hours at 10-m depth on a mooring at the Hawaii Ocean time series during the year 2005. Since dissolved N 2 is effectively inert to biological processes it can be used as a tracer for the physical mechanisms affecting the O 2 concentration in an upper ocean model of gas concentrations. We determine a net biological oxygen production in the surface mixed layer of 4.8 ± 2.7 mol m À2 yr À1 . The most important term in the mixedlayer mass balance other than biological oxygen production is the flux of oxygen across the air-water interface to the atmosphere. Simultaneous glider surveys of the O 2 field measured in a companion paper (Nicholson et al., 2008) yield net biological oxygen production below the mixed layer of 0.9 ± 0.1 mol O 2 m À2 yr À1. The upper-ocean mass balance also includes a potential contribution from diapycnal mixing of O 2 into the pycnocline of 0-0.8 mol O 2 m À2 yr À1 . Assuming that the net biological oxygen production over a period of a year or longer is stoichiometrically related to net biological carbon production and export via DO 2 /DC = 1.45, the biological carbon flux from the euphotic zone at HOT is 4.1 ± 1.9 mol C m À2 yr À1 in 2005, with roughly 80% of the carbon production originating in the mixed layer. Annual estimates of this flux (the ocean's ''biological carbon pump'') have been determined experimentally in only a few locations of the ocean because of the labor and expense involved in repeated ship board measurements. With this new in situ method, it may now be possible to better quantify the global distribution of the net annual biological carbon export, a prominent mechanism of carbon cycle feedback in response to climate change, both in the past and future.Citation: Emerson, S., C. Stump, and D. Nicholson (2008), Net biological oxygen production in the ocean: Remote in situ measurements of O 2 and N 2 in surface waters, Global Biogeochem. Cycles, 22, GB3023,

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“…NCP in the model was set using an idealized productivity curve from surface to compensation depth, with respiration below set in proportion to oxygen utilization rate (OUR) such that depth‐integrated NCP was zero following Stanley et al [2009]. The magnitude of euphotic zone NCP of O 2 was seasonally modulated following a sine curve peaking in June with an annual magnitude of 2.5 mol m −2 y −1 typical of subtropical rates of NCP [ Gruber et al , 1998; Stanley , 2007]. While the NCP parameterization influenced the net oxygen evolution in the model, it had only as small impact on 17 Δ dis because 17 Δ dis is not directly affected by respiration and is only weakly sensitive to changes in NCP.…”

Section: Methodsmentioning

confidence: 99%

Evaluating triple oxygen isotope estimates of gross primary production at the Hawaii Ocean Time‐series and Bermuda Atlantic Time‐series Study sites

et al. 2012

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[1] The triple oxygen isotopic composition of dissolved oxygen ( 17 D) is a promising tracer of gross oxygen productivity (P) in the ocean. Recent studies have inferred a high and variable ratio of P to 14 C net primary productivity (12-24 h incubations) (e.g., P:NPP( 14 C) of 5-10) using the 17 D tracer method, which implies a very low efficiency of phytoplankton growth rates relative to gross photosynthetic rates. We added oxygen isotopes to a one-dimensional mixed layer model to assess the role of physical dynamics in potentially biasing estimates of P using the 17 D tracer method at the Bermuda Atlantic Time-series Study (BATS) and Hawaii Ocean Time-series (HOT). Model results were compared to multiyear observations at each site. Entrainment of high 17 D thermocline water into the mixed layer was the largest source of error in estimating P from mixed layer 17 D. At both BATS and HOT, entrainment bias was significant throughout the year and resulted in an annually averaged overestimate of mixed layer P of 60 to 80%. When the entrainment bias is corrected for, P calculated from observed 17 D and 14 C productivity incubations results in a gross:net productivity ratio of 2.6 (+0.9 À0.8) at BATS. At HOT a gross:net ratio decreasing linearly from 3.0 (+1.0 À0.8) at the surface to 1.4 (+0.6 À0.6) at depth best reproduced observations. In the seasonal thermocline at BATS, however, a significantly higher gross:net ratio or large lateral fluxes of 17 D must be invoked to explain 17 D field observations.

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A determination of air-sea gas exchange and upper ocean biological production from five noble gases and tritiugenic helium-3

Cited by 5 publications

References 119 publications

Dissolved gases in the deep North Atlantic track ocean ventilation processes

Dissolved gases in the deep North Atlantic track ocean ventilation processes

Net biological oxygen production in the ocean: Remote in situ measurements of O₂ and N₂ in surface waters

Evaluating triple oxygen isotope estimates of gross primary production at the Hawaii Ocean Time‐series and Bermuda Atlantic Time‐series Study sites

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A determination of air-sea gas exchange and upper ocean biological production from five noble gases and tritiugenic helium-3

Cited by 5 publications

References 119 publications

Dissolved gases in the deep North Atlantic track ocean ventilation processes

Dissolved gases in the deep North Atlantic track ocean ventilation processes

Net biological oxygen production in the ocean: Remote in situ measurements of O2 and N2 in surface waters

Evaluating triple oxygen isotope estimates of gross primary production at the Hawaii Ocean Time‐series and Bermuda Atlantic Time‐series Study sites

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Net biological oxygen production in the ocean: Remote in situ measurements of O₂ and N₂ in surface waters