Global ocean carbon uptake: magnitude, variability and trends

Wanninkhof, Rik; Park, G. H.; Takahashi, Taro; Sweeney, C.; Feely, Richard A.; Nojiri, Yukihiro; Gruber, Nicolas; Doney, Scott C.; McKinley, Galen A.; Lenton, Andrew; Quéré, Corinne Le; Heinze, Christoph; Schwinger, J.; Graven, Heather; Khatiwala, S.

doi:10.5194/bg-10-1983-2013

Cited by 324 publications

(319 citation statements)

References 67 publications

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“…Therefore, any comparison over a 20-year period between models has the potential to be biased by the number of El Niño or La Niña events. Figure 15 shows that, in the period 1986-2005, ACCESS-ESM1 is in good agreement with the spatial pattern and the magnitude of sea-air CO 2 fluxes of Wanninkhof et al (2013), hereafter referred to as W13. In the Southern Ocean (44-90 • S), which is an important net sink of carbon, ACCESS-ESM1 (−0.77 PgC yr −1 ) captures a larger annual-mean uptake than the sea-air CO 2 flux of W13, which only estimated an uptake of −0.18 PgC yr −1 .…”

Section: Net Primary Productionsupporting

confidence: 52%

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The carbon cycle in the Australian Community Climate and Earth System Simulator (ACCESS-ESM1) – Part 2: Historical simulations

et al. 2017

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Abstract. Over the last decade many climate models have evolved into Earth system models (ESMs), which are able to simulate both physical and biogeochemical processes through the inclusion of additional components such as the carbon cycle. The Australian Community Climate and Earth System Simulator (ACCESS) has been recently extended to include land and ocean carbon cycle components in its ACCESS-ESM1 version. A detailed description of ACCESS-ESM1 components including results from pre-industrial simulations is provided in Part 1. Here, we focus on the evaluation of ACCESS-ESM1 over the historical period in terms of its capability to reproduce climate and carbon-related variables. Comparisons are performed with observations, if available, but also with other ESMs to highlight common weaknesses. We find that climate variables controlling the exchange of carbon are well reproduced. However, the aerosol forcing in ACCESS-ESM1 is somewhat larger than in other models, which leads to an overly strong cooling response in the land from about 1960 onwards. The land carbon cycle is evaluated for two scenarios: running with a prescribed leaf area index (LAI) and running with a prognostic LAI. We overestimate the seasonal mean (1.7 vs. 1.4) and peak amplitude (2.0 vs. 1.8) of the prognostic LAI at the global scale, which is common amongst CMIP5 ESMs. However, the prognostic LAI is our preferred choice, because it allows for the vegetation feedback through the coupling between LAI and the leaf carbon pool. Our globally integrated land-atmosphere flux over the historical period is 98 PgC for prescribed LAI and 137 PgC for prognostic LAI, which is in line with estimates of land use emissions (ACCESS-ESM1 does not include land use change).The integrated ocean-atmosphere flux is 83 PgC, which is in agreement with a recent estimate of 82 PgC from the Global Carbon Project for the period 1959-2005. The seasonal cycle of simulated atmospheric CO 2 is close to the observed seasonal cycle (up to 1 ppm difference for the station at Mace Head and up to 2 ppm for the station at Mauna Loa), but shows a larger amplitude (up to 6 ppm) in the high northern latitudes. Overall, ACCESS-ESM1 performs well over the historical period, making it a useful tool to explore the change in land and oceanic carbon uptake in the future.

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Section: Net Primary Productionsupporting

confidence: 52%

“…Sea-air CO 2 fluxes: seasonal climatology of Wanninkhof et al (2013) based on the 1 • × 1 • global measurements of oceanic pCO 2 of Takahashi et al (2009).…”

Section: Observationsmentioning

confidence: 99%

The carbon cycle in the Australian Community Climate and Earth System Simulator (ACCESS-ESM1) – Part 2: Historical simulations

et al. 2017

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“…While underway pCO 2 observations have greatly enhanced our understanding of the spatial variability in seaair CO 2 fluxes (Takahashi et al, 2009;Wanninkhof et al, 2013), they have not solved the problem of quantifying temporal variability at a given point in space. In highly variable regions such as the equatorial Pacific and coastal systems, fixed, high-frequency observations can improve our understanding of how short-term variability impacts CO 2 flux.…”

Section: Introductionmentioning

confidence: 99%

A high-frequency atmospheric and seawater <i>p</i>CO<sub>2</sub> data set from 14 open-ocean sites using a moored autonomous system

Sutton

Sabine

Maenner-Jones

et al. 2014

Earth Syst. Sci. Data

120

130

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Abstract.In an intensifying effort to track ocean change and distinguish between natural and anthropogenic drivers, sustained ocean time series measurements are becoming increasingly important. Advancements in the ocean carbon observation network over the last decade, such as the development and deployment of Moored Autonomous pCO 2 (MAPCO 2 ) systems, have dramatically improved our ability to characterize ocean climate, sea-air gas exchange, and biogeochemical processes. The MAPCO 2 system provides high-resolution data that can measure interannual, seasonal, and sub-seasonal dynamics and constrain the impact of shortterm biogeochemical variability on carbon dioxide (CO 2 ) flux. Overall uncertainty of the MAPCO 2 using in situ calibrations with certified gas standards and post-deployment standard operating procedures is < 2 µatm for seawater partial pressure of CO 2 (pCO 2 ) and < 1 µatm for air pCO 2 . The MAPCO 2 maintains this level of uncertainty for over 400 days of autonomous operation. MAPCO 2 measurements are consistent with shipboard seawater pCO 2 measurements and GLOBALVIEW-CO2 boundary layer atmospheric values. Here we provide an open-ocean MAPCO 2 data set including over 100 000 individual atmospheric and seawater pCO 2 measurements on 14 surface buoys from 2004 through 2011 and a description of the methods and data quality control involved. The climate-quality data provided by the MAPCO 2 have allowed for the establishment of open-ocean observatories to track surface ocean pCO 2 changes around the globe. Data are available at doi:10.3334/CDIAC/OTG.TSM_NDP092 and http://cdiac.ornl.gov/oceans/Moorings/ndp092.

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“…Data at higher temporal resolution is required to allow a more robust statistical evaluations of CO 2 fluxes over shorter time scales (Wanninkhof et al, 2013;Landschützer et al, 2014) and better constrain the mechanisms that drive the air sea fluxes (Schuster et al, 2013). This is of particular relevance to the North Atlantic sub-polar gyre, which forms an important CO 2 sink with sparse measurements (Corbière et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

Characterization of a Time-Domain Dual Lifetime Referencing pCO2 Optode and Deployment as a High-Resolution Underway Sensor across the High Latitude North Atlantic Ocean

et al. 2017

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The ocean is a major sink for anthropogenic carbon dioxide (CO 2 ), with the CO 2 uptake causing changes to ocean chemistry. To monitor these changes and provide a chemical background for biological and biogeochemical studies, high quality partial pressure of CO 2 (pCO 2 ) sensors are required, with suitable accuracy and precision for ocean measurements. Optodes have the potential to measure in situ pCO 2 without the need for wet chemicals or bulky gas equilibration chambers that are typically used in pCO 2 systems. However, optodes are still in an early developmental stage compared to more established equilibrator-based pCO 2 systems. In this study, we performed a laboratory-based characterization of a time-domain dual lifetime referencing pCO 2 optode system. The pCO 2 optode spot was illuminated with low intensity light (0.2 mA, 0.72 mW) to minimize spot photobleaching. The spot was calibrated using an experimental gas calibration rig prior to deployment, with a determined response time (τ 63 ) of 50 s at 25 • C. The pCO 2 optode was deployed as an autonomous shipboard underway system across the high latitude North Atlantic Ocean with a resolution of ca.10 measurements per hour. The optode data was validated with a secondary shipboard equilibrator-based infrared pCO 2 instrument, and pCO 2 calculated from discrete samples of dissolved inorganic carbon and total alkalinity. Further verification of the pCO 2 optode data was achieved using complimentary variables such as nutrients and dissolved oxygen. The shipboard precision of the pCO 2 sensor was 9.5 µatm determined both from repeat measurements of certified reference materials and from the standard deviation of seawater measurements while on station. Finally, the optode deployment data was used to evaluate the physical and biogeochemical controls on pCO 2 .

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Global ocean carbon uptake: magnitude, variability and trends

Cited by 324 publications

References 67 publications

The carbon cycle in the Australian Community Climate and Earth System Simulator (ACCESS-ESM1) – Part 2: Historical simulations

The carbon cycle in the Australian Community Climate and Earth System Simulator (ACCESS-ESM1) – Part 2: Historical simulations

A high-frequency atmospheric and seawater <i>p</i>CO<sub>2</sub> data set from 14 open-ocean sites using a moored autonomous system

Characterization of a Time-Domain Dual Lifetime Referencing pCO2 Optode and Deployment as a High-Resolution Underway Sensor across the High Latitude North Atlantic Ocean

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Global ocean carbon uptake: magnitude, variability and trends

Cited by 324 publications

References 67 publications

The carbon cycle in the Australian Community Climate and Earth System Simulator (ACCESS-ESM1) – Part 2: Historical simulations

The carbon cycle in the Australian Community Climate and Earth System Simulator (ACCESS-ESM1) – Part 2: Historical simulations

A high-frequency atmospheric and seawater &lt;i&gt;p&lt;/i&gt;CO&lt;sub&gt;2&lt;/sub&gt; data set from 14 open-ocean sites using a moored autonomous system

Characterization of a Time-Domain Dual Lifetime Referencing pCO2 Optode and Deployment as a High-Resolution Underway Sensor across the High Latitude North Atlantic Ocean

Contact Info

Product

Resources

About

A high-frequency atmospheric and seawater <i>p</i>CO<sub>2</sub> data set from 14 open-ocean sites using a moored autonomous system