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1. Atmospheric evidence for a global secular increase in carbon isotopic discrimination of land photosynthesis

Author

Keeling, Ralph F, Graven, Heather D, Welp, Lisa R, Resplandy, Laure, Bi, Jian, Piper, Stephen C, Sun, Ying, Bollenbacher, Alane, and Meijer, Harro AJ

Subjects
Life on Land, Atmosphere, Carbon Cycle, Carbon Dioxide, Carbon Isotopes, Climate Change, Fossil Fuels, Photosynthesis, Plants, Water, carbon cycle, photosynthesis, isotope, water use efficiency, carbon-13 Suess effect
Abstract

A decrease in the 13C/12C ratio of atmospheric CO2 has been documented by direct observations since 1978 and from ice core measurements since the industrial revolution. This decrease, known as the 13C-Suess effect, is driven primarily by the input of fossil fuel-derived CO2 but is also sensitive to land and ocean carbon cycling and uptake. Using updated records, we show that no plausible combination of sources and sinks of CO2 from fossil fuel, land, and oceans can explain the observed 13C-Suess effect unless an increase has occurred in the 13C/12C isotopic discrimination of land photosynthesis. A trend toward greater discrimination under higher CO2 levels is broadly consistent with tree ring studies over the past century, with field and chamber experiments, and with geological records of C3 plants at times of altered atmospheric CO2, but increasing discrimination has not previously been included in studies of long-term atmospheric 13C/12C measurements. We further show that the inferred discrimination increase of 0.014 ± 0.007‰ ppm-1 is largely explained by photorespiratory and mesophyll effects. This result implies that, at the global scale, land plants have regulated their stomatal conductance so as to allow the CO2 partial pressure within stomatal cavities and their intrinsic water use efficiency to increase in nearly constant proportion to the rise in atmospheric CO2 concentration.

Published
2017

2. COMPARABILITY OF RADIOCARBON MEASUREMENTS IN DISSOLVED INORGANIC CARBON OF SEAWATER PRODUCED AT ETH-ZURICH

Author

Castrillejo, Maxi, Hansman, Roberta L, Graven, Heather D, Lester, Joanna G, Bollhalder, Silvia, Kündig, Kayley, Wacker, Lukas, Boaretto, Elisabetta, Hajdas, Irka, and Synal, Hans-Arno

Abstract

ABSTRACTRadiocarbon observations (Δ14C) in dissolved inorganic carbon (DIC) of seawater provide useful information about ocean carbon cycling and ocean circulation. To deliver high-quality observations, the Laboratory of Ion Beam Physics (LIP) at ETH-Zurich developed a new simplified method allowing the rapid analysis of radiocarbon in DIC of small seawater samples, which is continually assessed by following internal quality controls. However, a comparison with externally produced 14C measurements to better establish an equivalency between methods was still missing. Here, we make the first intercomparison with the National Ocean Sciences Accelerator Mass Spectrometry (NOSAMS) facility based on 14 duplicate seawater samples collected in 2020. We also compare with prior deep-water observations from the 1970s to 1990s. The results show a very good agreement in both comparisons. The mean Δ14C of 12 duplicate samples measured by LIP and NOSAMS were statistically identical within one sigma uncertainty while two other duplicate samples agreed within two sigma. Based on this small number of duplicate samples, LIP values appear to be slightly lower than the NOSAMS values, but more measurements will be needed for confirmation. We also comment on storage and preservation techniques used in this study, including the freezing of samples collected in foil bags.

Published
2024
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3. Radiocarbon analysis reveals underestimation of soil organic carbon persistence in new-generation soil models.

Author

Brunmayr, Alexander S., Hagedorn, Frank, Moreno Duborgel, Margaux, Minich, Luisa I., and Graven, Heather D.

Subjects
SOIL profiles, SOIL stabilization, CARBON in soils, CARBON isotopes, TOPSOIL
Abstract

Reflecting recent advances in our understanding of soil organic carbon (SOC) turnover and persistence, a new generation of models increasingly makes the distinction between the more labile soil particulate organic matter (POM) and the more persistent mineral-associated organic matter (MAOM). Unlike the typically poorly defined conceptual pools of traditional SOC models, the POM and MAOM soil fractions can be directly measured for their carbon content and isotopic composition, allowing for fraction-specific data assimilation. However, the new-generation model predictions of POM and MAOM dynamics have not yet been validated with fraction-specific carbon and 14 C observations. In this study, we evaluate five influential and actively developed new-generation models (CORPSE, MEND, Millennial, MIMICS, SOMic) with fraction-specific and bulk soil 14 C measurements of 77 mineral topsoil profiles in the International Soil Radiocarbon Database (ISRaD). We find that all five models consistently overestimate the 14 C content (Δ14 C) of POM by 69 ‰ on average, and two out of the five models also strongly overestimate the Δ14 C of MAOM by more than 80 ‰ on average, indicating that the models generally overestimate the turnover rates of SOC and do not adequately represent the long-term stabilization of carbon in soils. These results call for more widespread usage of fraction-specific carbon and 14 C measurements for parameter calibration and may even suggest that some new-generation models might need to restructure or further subdivide their simulated carbon pools in order to accurately reproduce SOC dynamics. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Bomb radiocarbon evidence for strong global carbon uptake and turnover in terrestrial vegetation.

Author

Graven, Heather D., Warren, Hamish, Gibbs, Holly K., Khatiwala, Samar, Koven, Charles, Lester, Joanna, Levin, Ingeborg, Spawn-Lee, Seth A., and Wieder, Will

Subjects
*CARBON isotopes, *CARBON emissions, *CARBON cycle, *CARBON, *BOMBS
Abstract

Vegetation and soils are taking up approximately 30% of anthropogenic carbon dioxide emissions because of small imbalances in large gross carbon exchanges from productivity and turnover that are poorly constrained. We combined a new budget of radiocarbon produced by nuclear bomb testing in the 1960s with model simulations to evaluate carbon cycling in terrestrial vegetation. We found that most state-of-the-art vegetation models used in the Coupled Model Intercomparison Project underestimated the radiocarbon accumulation in vegetation biomass. Our findings, combined with constraints on vegetation carbon stocks and productivity trends, imply that net primary productivity is likely at least 80 petagrams of carbon per year presently, compared with the 43 to 76 petagrams per year predicted by current models. Storage of anthropogenic carbon in terrestrial vegetation is likely more short-lived and vulnerable than previously predicted. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Making the case for an International Decade of Radiocarbon

Author

Eglinton, Timothy I., primary, Graven, Heather D., additional, Raymond, Peter A., additional, Trumbore, Susan E., additional, Aluwihare, Lihini, additional, Bard, Edouard, additional, Basu, Sourish, additional, Friedlingstein, Pierre, additional, Hammer, Samuel, additional, Lester, Joanna, additional, Sanderman, Jonathan, additional, Schuur, Edward A. G., additional, Sierra, Carlos A., additional, Synal, Hans-Arno, additional, Turnbull, Jocelyn C., additional, and Wacker, Lukas, additional

Published
2023
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13. Trends and drivers of regional sources and sinks of carbon dioxide over the past two decades

Author

Sitch, Stephen, Friedlingstein, Pierre, Gruber, Nicolas, Jones, Steve D., Murray-Tortarolo, Guillermo, Ahlström, Anders, Doney, Scott C., Graven, Heather D., Heinze, Christoph, Huntingford, Chris, Levis, Samuel, Levy, Peter, Lomas, Mark, Poulter, Benjamin, Viovy, Nicolas, Zaehle, Sönke, Zeng, Ning, Arneth, Almuth, Bonan, Gordon, Bopp, Laurent, Canadell, Josep G., Chevallier, Frédéric, Ciais, Philippe, Ellis, Richard, Gloor, Manuel, Peylin, Philippe, Piao, Shilonog, Le Quéré, Corinne, Smith, Benjamin, Zhu, Zaichun, and Myneni, Ranga

Abstract

The land and ocean absorb on average just over half of the anthropogenic emissions of carbon dioxide (CO2) every year. These CO2 "sinks" are modulated by climate change and variability. Here we use a suite of nine dynamic global vegetation models (DGVMs) and four ocean biogeochemical general circulation models (OBGCMs) to estimate trends driven by global and regional climate and atmospheric CO2 in land and oceanic CO2 exchanges with the atmosphere over the period 1990–2009, to attribute these trends to underlying processes in the models, and to quantify the uncertainty and level of inter-model agreement. The models were forced with reconstructed climate fields and observed global atmospheric CO2; land use and land cover changes are not included for the DGVMs. Over the period 1990–2009, the DGVMs simulate a mean global land carbon sink of −2.4 ± 0.7 Pg C yr−1 with a small significant trend of −0.06 ± 0.03 Pg C yr−2 (increasing sink). Over the more limited period 1990–2004, the ocean models simulate a mean ocean sink of −2.2 ± 0.2 Pg C yr−1 with a trend in the net C uptake that is indistinguishable from zero (−0.01 ± 0.02 Pg C yr−2). The two ocean models that extended the simulations until 2009 suggest a slightly stronger, but still small, trend of −0.02 ± 0.01 Pg C yr−2. Trends from land and ocean models compare favourably to the land greenness trends from remote sensing, atmospheric inversion results, and the residual land sink required to close the global carbon budget. Trends in the land sink are driven by increasing net primary production (NPP), whose statistically significant trend of 0.22 ± 0.08 Pg C yr−2 exceeds a significant trend in heterotrophic respiration of 0.16 ± 0.05 Pg C yr−2 – primarily as a consequence of widespread CO2 fertilisation of plant production. Most of the land-based trend in simulated net carbon uptake originates from natural ecosystems in the tropics (−0.04 ± 0.01 Pg C yr−2), with almost no trend over the northern land region, where recent warming and reduced rainfall offsets the positive impact of elevated atmospheric CO2 and changes in growing season length on carbon storage. The small uptake trend in the ocean models emerges because climate variability and change, and in particular increasing sea surface temperatures, tend to counter\-act the trend in ocean uptake driven by the increase in atmospheric CO2. Large uncertainty remains in the magnitude and sign of modelled carbon trends in several regions, as well as regarding the influence of land use and land cover changes on regional trends., Biogeosciences Discussions, 10, ISSN:1810-6277, ISSN:1810-6285

Published
2013
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14. Global ocean carbon uptake: Magnitude,variability and trends

Author

Wanninkhof, Rik H., Park, Geunha, Takahashi, Taro, Sweeney, Colm, Feely, Richard A., Nojiri, Yukihiro, Gruber, Nicolas, Doney, Scott C., McKinley, Galen A., Lenton, Andrew, Le Quéré, Corinne, Heinze, Christoph, Schwinger, Jörg, Graven, Heather D., and Khatiwala, Samar P.

Abstract

Estimates of the anthropogenic global-integrated sea-air carbon dioxide (CO2) fluxfrom 1990 to 2009, based on different models and measurements, range from−1.4to−2.6 PgC yr−1. The median values of anthropogenic CO2for each method showbetter agreement and are:−1.9 for Pg C yr−1for numerical ocean general circulation hind cast models (OGCMs) with parameterized biogeochemistry;−2.1 PgC yr−1for at-mospheric inverse models;−1.9 PgC yr−1for global atmospheric constraints based onO2/ N2ratios for 1990–2000; and−2.4 PgC yr−1for oceanic inverse models. An up-dated estimate of this anthropogenic CO2flux based on a climatology of sea-air partialpressure of CO2differences (∆pCO2) (Takahashi et al., 2009) and a bulk formulation of gas transfer with wind speed for year 2000 is−2.0 PgC yr−1. Using this∆pCO2climatology and empirical relationships ofpCO2with sea-surface temperature (SST)anomalies (Park et al., 2010a), the interannual variability of the contemporary CO2flux is estimated to be 0.20Pg C yr−1(1σ) from 1990 through 2009. This is similar tothe variability estimated by the OGCMs of 0.16 Pg Cyr−1but smaller than the interannual variability from atmospheric inverse estimates of 0.40Pg C yr−1. The variability islargely driven by large-scale climate re-organizations. The decadal trends for differentmethods range from−0.13 (Pg Cyr−1) decade−1to−0.50 (Pg Cyr−1) decade−1. TheOGCMs and the data based sea-air CO2flux estimates show smaller uptakes and ap-preciably smaller decadal trends than estimates based on changes in carbon inventory suggesting that methods capable of resolving shorter timescales are showing a slow-ing of the rate of ocean CO2uptake. It is not clear if this large difference in trend is amethodological issue or a real natural feedback, Biogeosciences Discussions, 9, ISSN:1810-6277, ISSN:1810-6285

Published
2012

15. Global ocean storage of anthropogenic carbon

Author

Khatiwala, Samar P., Tanhua, Toste, Mikaloff Fletcher, Sara E., Gerber, Markus, Doney, Scott C., Graven, Heather D., Gruber, Nicolas, McKinley, G.A., Murata, Akihiko, Rios, A.F., Sabine, C.L., and Sarmiento, J.L.

Abstract

he global ocean is a significant sink for anthropogenic carbon (Cant), absorbing roughly a third of human CO2 emitted over the industrial period. Robust estimates of the magnitude and variability of the storage and distribution of Cant in the ocean are therefore important for understanding the human impact on climate. In this synthesis we review observational and model-based estimates of the storage and transport of Cant in the ocean. We pay particular attention to the uncertainties and potential biases inherent in different inference schemes. On a global scale, three data-based estimates of the distribution and inventory of Cant are now available. While the inventories are found to agree within their uncertainty, there are considerable differences in the spatial distribution. We also present a review of the progress made in the application of inverse and data assimilation techniques which combine ocean interior estimates of Cant with numerical ocean circulation models. Such methods are especially useful for estimating the air–sea flux and interior transport of Cant, quantities that are otherwise difficult to observe directly. However, the results are found to be highly dependent on modeled circulation, with the spread due to different ocean models at least as large as that from the different observational methods used to estimate Cant. Our review also highlights the importance of repeat measurements of hydrographic and biogeochemical parameters to estimate the storage of Cant on decadal timescales in the presence of the variability in circulation that is neglected by other approaches. Data-based Cant estimates provide important constraints on forward ocean models, which exhibit both broad similarities and regional errors relative to the observational fields. A compilation of inventories of Cant gives us a "best" estimate of the global ocean inventory of anthropogenic carbon in 2010 of 155 ± 31 PgC (±20% uncertainty). This estimate includes a broad range of values, suggesting that a combination of approaches is necessary in order to achieve a robust quantification of the ocean sink of anthropogenic CO2. ISSN:1810-6277 ISSN:1810-6285

Published
2012

16. Continental-scale enrichment of atmospheric 14CO2 from the nuclear power industry: potential impact on the estimation of fossil fuel-derived CO2

Author

Graven, Heather D. and Gruber, Nicolas

Abstract

Since aged carbon in fossil fuel contains no14C,14C/C ratios (∆14C) measured in at-mospheric CO2 can be used to estimate CO2 added by combustion and, potentially, provide verification of fossil CO2 emissions calculated using economic inventories. Sources of14C from nuclear power generation and spent fuel reprocessing can counteract dilution by fossil CO2. Therefore, these nuclear sources can bias observation-based estimates of fossil fuel-derived CO2if they are not correctly accounted for orincluded as a source of uncertainty. We estimate annual14C emissions from each nu-clear site in the world and conduct an Eulerian transport modeling study to investigatethe continental-scale, steady-state gradients of∆14C caused by nuclear activities and fossil fuel combustion. Over Europe, North America and East Asia, nuclear enrichmentmay offset 0–260 % of the fossil fuel dilution in∆14C, corresponding to potential biasesof 0 to−8 ppm in the CO2attributed to fossil fuel emissions, larger than the bias fromrespiration in some areas. Growth of14C emissions increased the potential nuclearbias over 1985–2005. The magnitude of this potential bias is largely independent of the choice of reference station in the context of Eulerian transport and inversion stud-ies, but could potentially be reduced by an appropriate choice of reference station inthe context of local-scale assessments., Atmospheric Chemistry and Physics, 11 (5), ISSN:1680-7375, ISSN:1680-7367

Published
2012

17. Continental-scale enrichment of atmospheric 14 CO2 from the nuclear power industry: potential impact on the estimation of fossil fuel-derived CO2

Author

Graven, Heather D. and Gruber, Nicolas

Abstract

The 14C-free fossil carbon added to atmospheric CO2 by combustion dilutes the atmospheric 14C/C ratio (Δ14C), potentially providing a means to verify fossil CO2 emissions calculated using economic inventories. However, sources of 14C from nuclear power generation and spent fuel reprocessing can counteract this dilution and may bias 14C/C-based estimates of fossil fuel-derived CO2 if these nuclear influences are not correctly accounted for. Previous studies have examined nuclear influences on local scales, but the potential for continental-scale influences on Δ14C has not yet been explored. We estimate annual 14C emissions from each nuclear site in the world and conduct an Eulerian transport modeling study to investigate the continental-scale, steady-state gradients of Δ14C caused by nuclear activities and fossil fuel combustion. Over large regions of Europe, North America and East Asia, nuclear enrichment may offset at least 20% of the fossil fuel dilution in Δ14C, corresponding to potential biases of more than −0.25 ppm in the CO2 attributed to fossil fuel emissions, larger than the bias from plant and soil respiration in some areas. Model grid cells including high 14C-release reactors or fuel reprocessing sites showed much larger nuclear enrichment, despite the coarse model resolution of 1.8°×1.8°. The recent growth of nuclear 14C emissions increased the potential nuclear bias over 1985–2005, suggesting that changing nuclear activities may complicate the use of Δ14C observations to identify trends in fossil fuel emissions. The magnitude of the potential nuclear bias is largely independent of the choice of reference station in the context of continental-scale Eulerian transport and inversion studies, but could potentially be reduced by an appropriate choice of reference station in the context of local-scale assessments., Atmospheric Chemistry and Physics, 11 (23), ISSN:1680-7375, ISSN:1680-7367

Published
2011
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18. Vertical profiles of biospheric and fossil fuel-derived CO2and fossil fuel CO2: CO ratios from airborne measurements of Δ14C, CO2and CO above Colorado, USA

Author

Graven, Heather D., Stephens, Britton B., Guilderson, Thomas P., Campos, Teresa L., Schimel, David S., Campbell, J. Elliott, and Keeling, Ralph F.

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, 13. Climate action, 01 natural sciences, 0105 earth and related environmental sciences
Abstract

Measurements of Δ14C in atmospheric CO2 are an effective method of separating CO2 additions from fossil fuel and biospheric sources or sinks of CO2. We illustrate this technique with vertical profiles of CO2 and Δ14C analysed in whole air flask samples collected above Colorado, USA in May and July 2004. Comparison of lower tropospheric composition to cleaner air at higher altitudes (>5 km) revealed considerable additions from respiration in the morning in both urban and rural locations. Afternoon concentrations were mainly governed by fossil fuel emissions and boundary layer depth, also showing net biospheric CO2 uptake in some cases. We estimate local industrial CO2:CO emission ratios using in situ measurements of CO concentration. Ratios are found to vary by 100% and average 57 mole CO2:1 mole CO, higher than expected from emissions inventories. Uncertainty in CO2 from different sources was ±1.1 to ±4.1 ppm for addition or uptake of −4.6 to 55.8 ppm, limited by Δ14C measurement precision and uncertainty in background Δ14C and CO2 levels.DOI: 10.1111/j.1600-0889.2009.00421.x

Published
2009
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25. Vertical profiles of biospheric and fossil fuel-derived CO2 and fossil fuel CO2 : CO ratios from airborne measurements of Δ14C, CO2 and CO above Colorado, USA.

Author

GRAVEN, HEATHER D., STEPHENS, BRITTON B., GUILDERSON, THOMAS P., CAMPOS, TERESA L., SCHIMEL, DAVID S., CAMPBELL, J. ELLIOTT, and KEELING, RALPH F.

Subjects
*ATMOSPHERIC carbon dioxide, *FOSSIL fuel power plants, *TROPOSPHERIC circulation, *TROPOSPHERIC chemistry, *EMISSIONS (Air pollution), *MERGERS & acquisitions
Abstract

Measurements of in atmospheric CO2 are an effective method of separating CO2 additions from fossil fuel and biospheric sources or sinks of CO2. We illustrate this technique with vertical profiles of CO2 and analysed in whole air flask samples collected above Colorado, USA in May and July 2004. Comparison of lower tropospheric composition to cleaner air at higher altitudes (>5 km) revealed considerable additions from respiration in the morning in both urban and rural locations. Afternoon concentrations were mainly governed by fossil fuel emissions and boundary layer depth, also showing net biospheric CO2 uptake in some cases. We estimate local industrial CO2:CO emission ratios using in situ measurements of CO concentration. Ratios are found to vary by 100% and average 57 mole CO2:1 mole CO, higher than expected from emissions inventories. Uncertainty in CO2 from different sources was ±1.1 to ±4.1 ppm for addition or uptake of −4.6 to 55.8 ppm, limited by measurement precision and uncertainty in background and CO2 levels. [ABSTRACT FROM AUTHOR]

Published
2009
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26. Recent trends and drivers of regional sources and sinks of carbon dioxide

Author

Sitch, Stephen, Friedlingstein, Pierre, Gruber, Nicolas, Jones, Steve D., Murray-Tortarolo, Guillermo, Ahlström, Anders, Doney, Scott C., Graven, Heather D., Heinze, Christoph, Huntingford, Chris, Levis, Samuel, Levy, Peter, Lomas, Mark, Poulter, Benjamin, Viovy, Nicolas, Zaehle, Sönke, Zeng, Ning, Arneth, Almuth, Bonan, Gordon, Bopp, Laurent, Canadell, Josep G., Chevallier, Frédéric, Ciais, Philippe, Ellis, Richard, Gloor, Manuel, Peylin, Philippe, Piao, Shilonog, Le Quéré, Corinne, Smith, Benjamin, Zhu, Zaichun, and Myneni, Ranga

Subjects
13. Climate action, 15. Life on land
Abstract

The land and ocean absorb on average just over half of the anthropogenic emissions of carbon dioxide (CO2) every year. These CO2 "sinks" are modulated by climate change and variability. Here we use a suite of nine dynamic global vegetation models (DGVMs) and four ocean biogeochemical general circulation models (OBGCMs) to estimate trends driven by global and regional climate and atmospheric CO2 in land and oceanic CO2 exchanges with the atmosphere over the period 1990–2009, to attribute these trends to underlying processes in the models, and to quantify the uncertainty and level of inter-model agreement. The models were forced with reconstructed climate fields and observed global atmospheric CO2; land use and land cover changes are not included for the DGVMs. Over the period 1990–2009, the DGVMs simulate a mean global land carbon sink of −2.4 ± 0.7 Pg C yr−1 with a small significant trend of −0.06 ± 0.03 Pg C yr−2 (increasing sink). Over the more limited period 1990–2004, the ocean models simulate a mean ocean sink of −2.2 ± 0.2 Pg C yr−1 with a trend in the net C uptake that is indistinguishable from zero (−0.01 ± 0.02 Pg C yr−2). The two ocean models that extended the simulations until 2009 suggest a slightly stronger, but still small, trend of −0.02 ± 0.01 Pg C yr−2. Trends from land and ocean models compare favourably to the land greenness trends from remote sensing, atmospheric inversion results, and the residual land sink required to close the global carbon budget. Trends in the land sink are driven by increasing net primary production (NPP), whose statistically significant trend of 0.22 ± 0.08 Pg C yr−2 exceeds a significant trend in heterotrophic respiration of 0.16 ± 0.05 Pg C yr−2 – primarily as a consequence of widespread CO2 fertilisation of plant production. Most of the land-based trend in simulated net carbon uptake originates from natural ecosystems in the tropics (−0.04 ± 0.01 Pg C yr−2), with almost no trend over the northern land region, where recent warming and reduced rainfall offsets the positive impact of elevated atmospheric CO2 and changes in growing season length on carbon storage. The small uptake trend in the ocean models emerges because climate variability and change, and in particular increasing sea surface temperatures, tend to counter\-act the trend in ocean uptake driven by the increase in atmospheric CO2. Large uncertainty remains in the magnitude and sign of modelled carbon trends in several regions, as well as regarding the influence of land use and land cover changes on regional trends., Biogeosciences, 12 (3), ISSN:1726-4170

27. Global ocean storage of anthropogenic carbon

Author

Khatiwala, Samar P., Tanhua, Toste, Mikaloff Fletcher, Sara E., Gerber, Markus, Doney, Scott C., Graven, Heather D., Gruber, Nicolas, McKinley, G.A., Murata, Akihiko, Rios, A.F., and Sabine, C.L.

Subjects
13. Climate action, 14. Life underwater
Abstract

The global ocean is a significant sink for anthropogenic carbon (Cant), absorbing roughly a third of human CO2 emitted over the industrial period. Robust estimates of the magnitude and variability of the storage and distribution of Cant in the ocean are therefore important for understanding the human impact on climate. In this synthesis we review observational and model-based estimates of the storage and transport of Cant in the ocean. We pay particular attention to the uncertainties and potential biases inherent in different inference schemes. On a global scale, three data-based estimates of the distribution and inventory of Cant are now available. While the inventories are found to agree within their uncertainty, there are considerable differences in the spatial distribution. We also present a review of the progress made in the application of inverse and data assimilation techniques which combine ocean interior estimates of Cant with numerical ocean circulation models. Such methods are especially useful for estimating the air–sea flux and interior transport of Cant, quantities that are otherwise difficult to observe directly. However, the results are found to be highly dependent on modeled circulation, with the spread due to different ocean models at least as large as that from the different observational methods used to estimate Cant. Our review also highlights the importance of repeat measurements of hydrographic and biogeochemical parameters to estimate the storage of Cant on decadal timescales in the presence of the variability in circulation that is neglected by other approaches. Data-based Cant estimates provide important constraints on forward ocean models, which exhibit both broad similarities and regional errors relative to the observational fields. A compilation of inventories of Cant gives us a "best" estimate of the global ocean inventory of anthropogenic carbon in 2010 of 155 ± 31 PgC (±20% uncertainty). This estimate includes a broad range of values, suggesting that a combination of approaches is necessary in order to achieve a robust quantification of the ocean sink of anthropogenic CO2., Biogeosciences, 10 (4), ISSN:1726-4170

28. Global ocean storage of anthropogenic carbon

Author

Khatiwala, Samar P., Tanhua, Toste, Mikaloff Fletcher, Sara E., Gerber, Markus, Doney, Scott C., Graven, Heather D., Gruber, Nicolas, McKinley, G.A., Murata, Akihiko, Rios, A.F., Sabine, C.L., and Sarmiento, J.L.

Subjects
13. Climate action, 14. Life underwater
Abstract

he global ocean is a significant sink for anthropogenic carbon (Cant), absorbing roughly a third of human CO2 emitted over the industrial period. Robust estimates of the magnitude and variability of the storage and distribution of Cant in the ocean are therefore important for understanding the human impact on climate. In this synthesis we review observational and model-based estimates of the storage and transport of Cant in the ocean. We pay particular attention to the uncertainties and potential biases inherent in different inference schemes. On a global scale, three data-based estimates of the distribution and inventory of Cant are now available. While the inventories are found to agree within their uncertainty, there are considerable differences in the spatial distribution. We also present a review of the progress made in the application of inverse and data assimilation techniques which combine ocean interior estimates of Cant with numerical ocean circulation models. Such methods are especially useful for estimating the air–sea flux and interior transport of Cant, quantities that are otherwise difficult to observe directly. However, the results are found to be highly dependent on modeled circulation, with the spread due to different ocean models at least as large as that from the different observational methods used to estimate Cant. Our review also highlights the importance of repeat measurements of hydrographic and biogeochemical parameters to estimate the storage of Cant on decadal timescales in the presence of the variability in circulation that is neglected by other approaches. Data-based Cant estimates provide important constraints on forward ocean models, which exhibit both broad similarities and regional errors relative to the observational fields. A compilation of inventories of Cant gives us a "best" estimate of the global ocean inventory of anthropogenic carbon in 2010 of 155 ± 31 PgC (±20% uncertainty). This estimate includes a broad range of values, suggesting that a combination of approaches is necessary in order to achieve a robust quantification of the ocean sink of anthropogenic CO2., Biogeosciences Discussions, 9, ISSN:1810-6277, ISSN:1810-6285

29. Global ocean carbon uptake: Magnitude, variability and trends

Author

Wanninkhof, Rik, Park, Geun Ha, Takahashi, Taro, Sweeney, Colm, Feely, Richard A., Nojiri, Yukihiro, Gruber, Nicolas, Doney, Scott C., McKinley, Galen A., Lenton, Andrew, Le Quéré, Corinne, Heinze, Christoph, Schwinger, Jörg, Graven, Heather D., and Khatiwala, Samar P.

Subjects
13. Climate action, 14. Life underwater
Abstract

The globally integrated sea–air anthropogenic carbon dioxide (CO2) flux from 1990 to 2009 is determined from models and data-based approaches as part of the Regional Carbon Cycle Assessment and Processes (RECCAP) project. Numerical methods include ocean inverse models, atmospheric inverse models, and ocean general circulation models with parameterized biogeochemistry (OBGCMs). The median value of different approaches shows good agreement in average uptake. The best estimate of anthropogenic CO2 uptake for the time period based on a compilation of approaches is −2.0 Pg C yr−1. The interannual variability in the sea–air flux is largely driven by large-scale climate re-organizations and is estimated at 0.2 Pg C yr−1 for the two decades with some systematic differences between approaches. The largest differences between approaches are seen in the decadal trends. The trends range from −0.13 (Pg C yr−1) decade−1 to −0.50 (Pg C yr−1) decade−1 for the two decades under investigation. The OBGCMs and the data-based sea–air CO2 flux estimates show appreciably smaller decadal trends than estimates based on changes in carbon inventory suggesting that methods capable of resolving shorter timescales are showing a slowing of the rate of ocean CO2 uptake. RECCAP model outputs for five decades show similar differences in trends between approaches., Biogeosciences, 10 (3), ISSN:1726-4170

30. A special issue preface: Radiocarbon in the Anthropocene.

Author

Eglinton TI, Graven HD, Raymond PA, and Trumbore SE

Abstract

The Anthropocene is defined by marked acceleration in human-induced perturbations to the Earth system. Anthropogenic emissions of CO 2 and other greenhouse gases to the atmosphere and attendant changes to the global carbon cycle are among the most profound and pervasive of these perturbations. Determining the magnitude, nature and pace of these carbon cycle changes is crucial for understanding the future climate that ecosystems and humanity will experience and need to respond to. This special issue illustrates the value of radiocarbon as a tool to shed important light on the nature, magnitude and pace of carbon cycle change. This article is part of the Theo Murphy meeting issue 'Radiocarbon in the Anthropocene'.

Published
2023
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31. Making the case for an International Decade of Radiocarbon.

Author

Eglinton TI, Graven HD, Raymond PA, Trumbore SE, Aluwihare L, Bard E, Basu S, Friedlingstein P, Hammer S, Lester J, Sanderman J, Schuur EAG, Sierra CA, Synal HA, Turnbull JC, and Wacker L

Abstract

Radiocarbon ( 14 C) is a critical tool for understanding the global carbon cycle. During the Anthropocene, two new processes influenced 14 C in atmospheric, land and ocean carbon reservoirs. First, 14 C-free carbon derived from fossil fuel burning has diluted 14 C, at rates that have accelerated with time. Second, 'bomb' 14 C produced by atmospheric nuclear weapon tests in the mid-twentieth century provided a global isotope tracer that is used to constrain rates of air-sea gas exchange, carbon turnover, large-scale atmospheric and ocean transport, and other key C cycle processes. As we write, the 14 C/ 12 C ratio of atmospheric CO 2 is dropping below pre-industrial levels, and the rate of decline in the future will depend on global fossil fuel use and net exchange of bomb 14 C between the atmosphere, ocean and land. This milestone coincides with a rapid increase in 14 C measurement capacity worldwide. Leveraging future 14 C measurements to understand processes and test models requires coordinated international effort-a 'decade of radiocarbon' with multiple goals: (i) filling observational gaps using archives, (ii) building and sustaining observation networks to increase measurement density across carbon reservoirs, (iii) developing databases, synthesis and modelling tools and (iv) establishing metrics for identifying and verifying changes in carbon sources and sinks. This article is part of the Theo Murphy meeting issue 'Radiocarbon in the Anthropocene'.

Published
2023
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