- 1Polar and Marine Research Institute, Jimei University, Xiamen, China
- 2Ocean and Earth Science, National Oceanography Centre Southampton, University of Southampton, Southampton, United Kingdom
The Southern Ocean absorbs a quarter of anthropogenic carbon dioxide (CO2) from the atmosphere to modulate the climate system. However, less attention has been paid to the CO2 outgassing phenomenon at the Antarctic Circumpolar Current (ACC) region of the Southern Ocean due to strong upwelling. Recent studies using autonomous biogeochemical-Argo float revealed a greater winter CO2 outgassing than previously estimated at ACC zone of the Southern Ocean, which, however, remains controversial and urgently needs to be validated. Here we take the Drake Passage as a case study to present new insights into the Southern Ocean carbon cycle and examine the validity of float-based CO2 outgassing. Upon integrating the ship-based data over the past two decades, we investigate the spatiotemporal variability of sea surface CO2 partial pressure (pCO2) in Drake Passage. We show that Drake Passage is acting as a year-round weak CO2 sink, although some CO2 uptake is counteracted by winter CO2 outgassing. The float-based pCO2 values are overall higher than ship-based values in winter, by 6 to 20 µatm (averaged 14 µatm) at the most intensive upwelling region. We then develop a surface carbon balance calculation (considering mixing between surface, subsurface, and upwelled waters) to estimate the potential of surface pCO2 increase due to upwelling, and we find that upwelling of CO2-rich subsurface waters in Drake Passage cannot support an excess ΔpCO2 of 14 µatm as suggested by float detections. We further compare our results to previous study and find that, although we used same datasets and obtained comparable results, the way to conclude the bias in float-based pCO2 would cause significant difference: an uncertainty of ±2.7% (i.e., ± 11 µatm) in float-based pCO2 estimated by other study seems acceptable, however, it is five times larger than the typical ship-based pCO2 uncertainty ( ± 2 µatm), and would cause ~180% bias in CO2 flux estimates. Going forward, there is special need for caution when interpreting the float-based CO2 flux; meanwhile, further comparisons and corrections between float- and ship-based pCO2 are clearly warranted.
1 Introduction
The Southern Ocean plays an outsized role in the global carbon cycle and therefore regulating the global climate system (Sarmiento & Toggweiler, 1984; Gruber et al., 2019a; Gruber et al., 2019b). The Southern Ocean (south of 30°S) is responsible for a disproportionately large percentage (~40%) of the total oceanic sink of anthropogenic CO2 (Mikaloff Fletcher et al., 2006; Gruber et al., 2009; DeVries, 2014; Gruber et al., 2019a; Gruber et al., 2019b), as well as the large-scale control of nutrient supplies to the low-latitude oceans and therefore the magnitude of low-latitude biological productivity (Sarmiento et al., 2004). Observations and models have demonstrated large variability in the efficiency of uptake of CO2 in the Southern Ocean over the past few decades. The strength of the Southern Ocean CO2 sink was reported to have slackened from the 1980s to the early 2000s due to the increase in Southern Ocean winds which enhances the upwelling and outgassing of natural CO2 (Le Quéré et al., 2007; Lovenduski et al., 2008). In contrast, recent studies (Landschützer et al., 2015; Munro et al., 2015b) suggest reinvigoration of the Southern Ocean CO2 uptake since 2002, due to the cooling in the Pacific Ocean, enhanced stratification in the Atlantic and Indian Ocean sectors, and a reduced overturning (Landschützer et al., 2015; DeVries et al., 2017; Gruber et al., 2019b).
The Southern Ocean is uniquely important due in large part to its circulation. Deep waters from both the Atlantic and the Indo-Pacific are upwelled to the surface, and then transformed into intermediate waters or denser bottom waters (Lumpkin & Speer, 2007; Marshall & Speer, 2012; Talley, 2013). The upwelling mostly occurs at the southern portion of the Antarctic Circumpolar Current (ACC) (Orsi et al., 1995; Thorpe et al., 2002; Chapman et al., 2020), where deep waters return to the upper ocean via wind-driven Ekman transport (Marshall & Speer, 2012) and release the remineralized CO2 that has been accumulated and isolated from the atmosphere over centuries. Such CO2 release is concentrated to a relatively narrow band between 50°S and 65°S (Chen et al., 2022). Previous studies (e.g., Wu et al., 2019) have demonstrated a strong latitudinal gradient in surface dissolved inorganic carbon (DIC), where DIC is highest in the high-latitude Southern Ocean as a consequence of low temperature and upwelling; and high-DIC subsurface waters outcrop along the upwelling pathway. However, this might not be identical to the partial pressure of CO2 (pCO2, which fundamentally matters to air-sea CO2 exchange) given that pCO2 is also regulated by the excess total alkalinity (TA), seawater temperature and salinity, resulting in a distinct vertical distribution of pCO2 (Chen et al., 2022). Therefore, a more comprehensive understanding of the upwelling impacts on surface pCO2 is required to decipher the mechanism of upwelling-induced deep CO2 release.
Despite its vital impact on the carbon cycle and climate system, the Southern Ocean remains one of the most poorly sampled regions of the global ocean and characterized by large uncertainty in CO2 flux estimates (Bakker et al., 2016; Gruber et al., 2019b; Friedlingstein et al., 2022). The Drake Passage is, however, an exception with a lot of high-frequency and high-resolution observational data made since 2002 as part of the Drake Passage Time-series Project. The carbon cycle and carbonate system in Drake Passage is consequently better understood (Munro et al., 2015a; Munro et al., 2015b; Fay et al., 2018) than elsewhere in the Southern Ocean, and suggested to be representative of a broader region in the subpolar Southern Ocean in both seasonality and long-term CO2 trends.
With the aim of filling data gaps and gaining better understandings of the Southern Ocean carbon cycle, starting since 2014, the Southern Ocean Carbon and Climate Observations and Modeling (SOCCOM) program has deployed the first biogeochemical float array across the Southern Ocean. More than 200 floats, equipped with oxygen, nitrate, pH, and bio-optical sensors (Johnson et al., 2017) have been released (https://soccom.princeton.edu/). The carbonate system data (e.g., pCO2) were derived from the float-measured pH and algorithm-calculated TA. Based on the first several years of limited SOCCOM data, Williams et al. (2017); Gray et al. (2018) and Bushinsky et al. (2019) showed a surprisingly large CO2 outgassing signal around the ACC zone, in particular in winter, at a much greater rate (0.36 Pg C year-1) than previous ship-based estimates (from -0.05 to 0.03 Pg C year-1; according to Landschützer et al., 2014 and Takahashi et al., 2009). They attributed the increases in the carbon and nutrient content of surface waters in the high-latitude Southern Ocean primarily to the scarcity of pCO2 observations prior to the float measurements being available as well as interannual variability, e.g., a positive Southern Ocean Annular Mode Index over 2014-2017 resulted in increased wind-driven upwelling (Lovenduski et al., 2007; Lovenduski et al., 2008). However, some recent evidences with independent approaches (e.g., airborne observations, uncrewed surface vehicle observations, reconstructions of winter data, and paired CO2-O2 metrics; Long et al., 2021; Mackay & Watson, 2021; Sutton et al., 2021; Wu et al., 2022) showed that the biogeochemical-Argo might have overestimated sea surface pCO2, thus adding more controversy to the accurate estimates of CO2 flux. The discrepancy between ship-based and float-based estimates of surface pCO2 and air-sea exchange therefore motivated us to examine the validity of such strong CO2 outgassing in the ACC zone of the Southern Ocean. For this purpose, we take advantage of the Drake Passage dataset and its representation of the subpolar Southern Ocean carbon cycle to investigate the ship-based seasonal variability of sea surface pCO2. In order to gain a mechanistic understanding, we develop a surface carbon balance calculation (accounting for deep entrainment of CO2 from subsurface water and upwelled water) to estimate the theoretical value of winter surface pCO2 under the influence of vertical mixing and upwelling.
2 Materials and methods
2.1 Study area: Drake Passage
The strong flow of the zonally unbounded Antarctic Circumpolar Current (ACC) is constricted to as narrow as ~800 km, making Drake Passage a natural laboratory for investigating the entire ACC system over a relatively short distance (Sprintall et al., 2012). We followed the previous studies (Munro et al., 2015a; Munro et al., 2015b) to divide Drake Passage into four regions according to its unique physical oceanography and geographic settings. The four regions (Figure 1A) in Drake Passage are oriented parallel to the Antarctic Polar Front (APF) and the mean flow of the ACC, with two of them (R1 and R2) located north of the APF and the other two (R3 and R4) located south of the APF. The Subantarctic Front (SAF) locates within R1, the APF locates between R2 and R3.
Figure 1 The observations from ship-based underway measurements and biogeochemical-Argo float in the Drake Passage. (A) underway pCO2 measurements indicated by grey lines. The black dashed line indicates the location of SAF, black solid line indicates APF, and black dotted line indicates southern ACC front (front data obtained from Orsi et al., 1995; Thorpe et al., 2002). The cruises with water column sampling are denoted by purple and pink lines, in February 2009 and March 2006/September 2009, respectively. The coordinates of the box corners from the top corner of R1 to the bottom corner of R4 are: 55.06°S, 63.29°W; 57.52°S, 70.97°W; 56.49°S, 61.87°W; 58.95°S, 69.85°W; 57.92°S, 60.39°W; 60.38°S, 68.71°W; 59.34°S, 58.85°W; 61.81°S, 67.54°W; 60.77°S, 57.26°W; and 63.24°S, 66.35°W. (B) Argo floats that intersected the study area. Eight floats were selected.
2.2 Data source
We used several observational datasets containing surface pCO2 and carbonate system parameters as described below. The austral summer is defined as from January to March, and so on for the other seasons.
2.2.1 The time-series data in Drake Passage
Discrete surface samples for parameters (e.g., salinity, macronutrients, and DIC) as well as high-frequency underway pCO2 measurements were collected and measured on five to eight transects of Drake Passage per year by the Antarctic Research Supply Vessel Laurence M. Gould. The carbonate system parameters as well as other biogeochemical variables measured onboard (referred to as Drake Passage Time-series, DPT) allow for a comprehensive understanding of the biogeochemistry in Drake Passage. The DPT dataset during 2002 to 2017 (Figure 1A) was downloaded from https://www.ldeo.columbia.edu/res/pi/CO2/. The analytical precision was ±2 µatm for underway pCO2, and approximately ±1 µmol kg-1 for DIC (Munro et al., 2015a; Munro et al., 2015b). TA was calculated from DIC, pCO2, temperature, salinity, phosphate, and silicate data. The estimated accuracy of each TA value was 2 µmol kg-1 based on the analytical precision of pCO2 and DIC (Takahashi et al., 2014; Munro et al., 2015a; Munro et al., 2015b). The computed TA values were relatively close to the measured TA values (of the samples with pCO2, DIC, and TA measurements) by titration (root-mean-square deviation of ±4 µmol kg-1).
We also took advantage of the existing water column profiles in Drake Passage in March 2006, February and September 2009 (Figure 1A). The data were obtained from the GLODAPv2.2020 dataset (Olsen et al., 2020), with uncertainties of 4 µmol kg-1 and 6 µmol kg-1 for DIC and TA, respectively.
2.2.2 SOCCOM float data
The SOCCOM Biogeochemical-Argo float data were downloaded from https://soccom.princeton.edu/, and 8 floats intersecting Drake Passage (from 2014 to 2020) were used in this study (Figure 1B). The float measures water column pH, oxygen, nitrate, fluorescence, and backscattering (Johnson et al., 2017). Carbonate system parameters including pCO2 and others are first calculated from sensor-measured temperature, salinity, pH, LIAR algorithm-estimated TA, and silicate and phosphate concentrations (Williams et al., 2016; Williams et al., 2017; Carter et al., 2018). All float data were quality controlled as described in Johnson et al. (2017). Specifically, the quality control of pH data is based on the crossover analysis for deep waters between float and shipboard (including available Southern Ocean dataset and SOCCOM deployment cruises) measurements. The empirical algorithm for estimating in-situ pH as a function of temperature, salinity, pressure, and O2 is determined for shipboard bottle measurements at 1000-2000 m depth, which is then applied to float-measured temperature, salinity, pressure, and O2. By comparing the two pH values at 1500 m depth, an offset in pH is applied to the entire float profile. The measured pH has a reported uncertainty of 1% (equivalent to 0.005) respectively (Johnson et al., 2017), and the estimated TA and pCO2 have a reported uncertainty of 5.6 µmol kg-1 and 2.7% respectively (Williams et al., 2017).
The uncertainty associated with the float-estimated pCO2 mainly results from three factors: accuracy of the estimated TA, accuracy of the measured pH, and the choice of equilibrium constants used for calculating the carbonate system (Williams et al., 2017). Among them, the accuracy of the measured pH was proven to be the dominant factor (Williams et al., 2017; Takeshita et al., 2018). According to a quality control assessment through December 2016 (Johnson et al., 2017), the pH sensor was recorded to have the lowest percentage (88%) of good data return, while the oxygen sensor had the best percentage (100%) of good data return. Some previous efforts have been made to reveal the mismatch between float-based and ship-based pH values (Álvarez et al., 2020; Wu et al., 2022).
2.3 Data processing
2.3.1 Detrend of pCO2
In order to prevent the temporal CO2 trends from generating artificial spatial variability due to anthropogenic CO2 influence, we detrended the surface pCO2 and normalized it to a reference year 2005 for a better comparison with global studies (e.g., Takahashi et al., 2014). The rate of trend of 1.67 µatm yr-1 accounting for increasing atmospheric CO2 during the 2002-2017 period was determined from the underway pCO2 measurements used in this study (Figure 2A). The rate varies slightly across the particular region (R1-R4) in the Drake Passage, with deviations less than 0.23 µatm yr-1 (Figures 2B–E), which equals to 2.76 µatm bias for a 12-year normalization from 2005 to 2017. This is within the uncertainty of pCO2 measurements and therefore could be negligible. We further applied this rate to the entire Drake Passage when normalizing the ship-based and float-based pCO2 to 2005.
Figure 2 The inter-annual variation in surface pCO2 in the Drake Passage (A) and specifically in its four regions (B–E) The grey dots are the raw pCO2 data, the red dots are the monthly mean pCO2 values. The slope of linear regression is used to detrend surface pCO2.
2.3.2 Surface carbon balance calculation
Figure 3 shows the seasonal changes in water mass properties in Drake Passage (Evans et al., 2014). In winter, a large amount of Antarctic Winter Water (AAWW) and Antarctic Intermediate Water (AAIW) are formed due primarily to strong surface cooling and consequent deep mixed layers, whilst in summer, AAWW is eroded through surface warming and interior mixing with surface water until the following winter. Compared to the surface water in either summer or winter, AAWW is supposed to exhibit increased salinity and DIC (Table 1). By quantifying the individual contributions of Summer Surface Water (SSW) and AAWW to the surface carbon balance in Winter Surface Water (WSW), we can then reach an estimate of how seasonal water mass transformation changes surface DIC and pCO2.
Figure 3 Schematic showing the changes in the distributions of water masses during (A) summer and (B) winter in depth vs. latitude coordinates. The black circles with dots represent the direction of the zonal winds out of the page. SSW, Summer Surface Water; WSW, Winter Surface Water; AAWW, Antarctic Winter Water; SAMW, Subantarctic Mode Water; AAIW, Antarctic Intermediate Water; UCDW/LCDW, Upper/Lower Circumpolar Deep Water. Figure modified from Evans et al. (2014).
Table 1 Values of absolute salinity (SA), conservative temperature (Tcons), TA, and DIC in each endmember water mass.
Due to the fact that most of the float-observed strong CO2 outgassing occurs in the ACC zone (Williams et al., 2017; Gray et al., 2018), we combined zone R3 and R4 (south of APF and north of southern ACC) in Drake Passage (Figure 1) to investigate the surface carbon balance. During the mixing of SSW and AAWW to form WSW, the fraction of AAWW (fAAWW) was calculated as the amount necessary to change the surface concentration [X] of a specific tracer from its observed value at the beginning of the entrainment (i.e., summer months) period to the value at the end of the entrainment (i.e., winter months), according to Equations 1 and 2:
where [X]SSW is the concentration in Summer Surface Water, and [X]WSW is for Winter Surface Water. In addition, we also considered the mixture of Upper Circumpolar Deep Water (UCDW) and SSW to form WSW which is an extreme scenario that barely happens in the study area (Figure 3A). In this case the endmember AAWW was replaced by UCDW. Two conservative parameters, total alkalinity (TA) and absolute salinity (SA), were chosen to quantify this process separately. The absolute salinity is defined as the mass fraction of salt in seawater as opposed to practical salinity which is essentially a measure of the conductivity of seawater to describe the salt content of seawater; absolute salinity is an SI unit of concentration with units of g kg-1.
The AAWW water mass is defined by its characteristic ranges in absolute salinity and conservative temperature (Tcons), with SA ranging from 34 g kg-1 to 34.3 g kg-1, and Tcons ranging from -2°C to 1°C (Evans et al., 2014). The conservative temperature is a new standard for ocean temperature adopted by the oceanographic community as part of the Thermodynamic Equation of Seawater – 2010 (TOES-10), which is based on a hypothetical adiabatic and isohaline change in pressure to the sea surface. Table 1 summarizes the average values of the two tracers as well as the carbonate parameters in each mixing endmember; the values for AAWW and UCDW were taken from depth profile data, and the values for SSW and WSW were taken from the detrended surface underway data. The Gibbs-SeaWater Toolbox was used to calculate absolute salinity and conservative temperature.
Uncertainties for the calculated fractions of different water masses and the subsequent mixed DIC and pCO2 were estimated from a 1000-iteration Monte Carlo analysis that contained uncertainties of each input parameters as listed in Table 1. The principle of Monte Carlo analysis follows Wu et al. (2019).
3 Results
3.1 Spatiotemporal variability of ship-based surface pCO2 in Drake Passage
The surface pCO2 (normalized to reference year 2005) displayed distinct patterns in each season across the four regions in Drake Passage (Figure 4). Spatially, surface pCO2 exhibit an overall decreasing trend against latitude in spring, autumn, and winter; however, became more dynamic in summer due to the possible interaction with biological activity (Brown et al., 2019). Noteworthy, a hotspot of high pCO2 was found in R4 particularly in spring and winter, which is due to upwelling around ACC zone. The latitudinal gradient in pCO2 was sizable in both summer and winter, with spatial variation of up to 50 µatm in winter. Temporally, summer surface waters pCO2 ranged from 300 to 370 µatm, which were mostly undersaturated with respect to the atmospheric pCO2 (366 µatm in 2005); however, most of them became supersaturated in winter. The regions south of the APF experienced the greatest seasonal variation in pCO2 (~80 µatm).
Figure 4 The spatial distribution of ship-based and float-based pCO2 in each season in the surface Drake Passage. (A–D) spring to winter. pCO2 was normalized to year 2005.
Figures 5, 6 show the seasonal variation of surface pCO2 and ΔpCO2 (sea surface pCO2 minus atmospheric pCO2) from R1 to R4. Overall, the region acts as a weak sink of CO2 from the atmosphere (Fig. 6E), with R1 and R2 being a near neutral region (winter CO2 source counteracted by summer sink), and R3 and R4 being a sink region (persistent CO2 sink except for a couple of months). The maxima of surface ocean pCO2 were often reached in austral winter, when upward transport of deep water brings CO2-rich water to the surface, and the minima were mostly observed in summer, when biological production draws down the surface CO2 level (Takahashi et al., 2009). The seasonal amplitude of ΔpCO2 is generally less than 10 µatm throughout Drake Passage (Figures 6A–D), in agreement with the comprehensive study of surface pCO2 in Drake Passage carried out by Fay et al. (2018) and Munro et al. (2015b).
Figure 5 The comparison between ship-based and float-based monthly pCO2 in each region (A–D) of the Drake Passage.
Figure 6 The comparison between ship-based and float-based monthly ΔpCO2 in each region of the Drake Passage. (A–D) monthly ΔpCO2 in different regions from R1 to R4. (E) the spatial pattern of ΔpCO2. ΔpCO2 means difference between the sea surface and atmospheric pCO2. The error bars represent the standard deviations of monthly mean values.
3.2 Comparisons between ship- and float-based carbonate parameters
We constrained the 8 floats within R1-R4 regions. For comparison between different sampling years, both the ship-based and float-based pCO2 were adjusted to the reference year 2005 according to the reported rates of anthropogenic change in the Southern Ocean (see Section 2.3.1). Since the Argo float collected data from surface to deep (2000 m) during a 10-day cycle, it happened that most of the data located in R4, and most of them were collected in winter. Significant disagreement between the ship- and float-based pCO2 and ΔpCO2 were found in R4 (Figures 4–6).
In R4, float-based pCO2 and ΔpCO2 were significantly higher than ship-based except for a couple of months (November and December). Since the atmospheric pCO2 is rather stable in the southern hemisphere, the deviations in pCO2 are therefore equivalent to deviations in ΔpCO2. Such deviations (float minus ship) seem to be consistent through February to September, ranging from 6 to 24 µatm (averaged 14 µatm), with largest deviations in autumn and winter (May to August). This suggests a possible overestimation of pCO2 and ΔpCO2 by float-based observations. In terms of pCO2, this overestimation means 2-6% uncertainty (6-24 µatm divided by mean pCO2 of 363 µatm); however, in terms of ΔpCO2, this would mean 100-400% uncertainty (6-24 µatm divided by mean of absolute ΔpCO2 value of 6 µatm).
4 Discussion
4.1 The theoretical envelope of upwelling-induced pCO2
Tracer values from Table 1 were applied to Equations 1-2 to estimate the fractions of AAWW and SSW present in surface water. DIC is conservative regarding the mixing process but affected by biogeochemical processes, therefore we calculated (using Equation 2) the concentrations of ‘mixed’ DIC in WSW just from mixing of AAWW and SSW DIC values; pCO2 is not conservative regarding the mixing process, the values of ‘mixed’ pCO2 in WSW were therefore calculated from the carbonate system with the inputs of ‘mixed’ TA and ‘mixed’ DIC, using CO2SYS (Van Heuven et al., 2011). The choice of dissociation constants was following the global scale studies such as Wu et al. (2019).
Using TA as tracer resulted in calculated fractions of AAWW=13% and SSW=87% (fraction uncertainty of 20%), and subsequent mixed DIC of 2139 ± 13 µmol kg-1 and pCO2 = 307 ± 27 µatm, both of which are less than the observed levels in the WSW and atmosphere. Using salinity as tracer resulted in calculated fractions of AAWW = 48% (more upwelled waters than TA-derived) and SSW = 52% (fraction uncertainty of 24%), and subsequent mixed DIC of 2153 ± 15 µmol kg-1 and pCO2 = 337 ± 22 µatm, still less than the observed levels in the WSW and atmosphere.
Moreover, even if we accounted for the mixture between UCDW, AAWW, and SSW to form WSW, the results still yielded lower pCO2 (‘mixed’ pCO2 ranged between 310 ± 30 and 330 ± 34 µatm, with UCDW fraction ranging from 6 ± 10% to 14 ± 10% depending on different tracers) than the atmospheric level. Although it seems counterintuitive because UCDW endmember could provide enormous natural carbon to the surface ocean (DeVries et al., 2017), the mixed pCO2 would be as low as calculated because of the countering effect from high upwelled TA (Wu et al., 2019; Chen et al., 2022).
Despite that the estimated surface pCO2 from winter entrainment and upwelling exhibited deviations between different choice of tracers, they served as sensitivity test to each other and both suggested much lower levels of pCO2 than atmospheric level. The physically ‘mixed’ pCO2 was therefore not capable of inducing strong CO2 outgassing (consistent with Figure 5); R4 thus remained a CO2 sink region, which also agrees well with a previous assessment that Drake Passage is overall a persistent CO2 sink in all regions (Munro et al., 2015b; Fay et al., 2018).
4.2 Is the strong winter CO2 source plausible?
Our results imply that Drake Passage is a weak oceanic sink for CO2 (Figure 6) and challenge the finding from SOCCOM float data that high-latitude Southern Ocean releases substantial CO2 (Williams et al., 2017; Gray et al., 2018; Bushinsky et al., 2019). Both approaches used in this study suggest that it is implausible that winter entrainment/upwelling of deep waters into Drake Passage surface layer could produce a magnitude in ΔpCO2 of as large as 40 µatm (which was suggested by float estimations; Williams et al., 2017) or a remarkable natural CO2 outgassing signal (Bushinsky et al., 2019). The upwelling of high pCO2 subsurface waters is therefore limited in causing large winter outgassing from just beneath the surface mixed layer in Drake Passage of the high-latitude Southern Ocean. Although we did not extend our approach to the wider Southern Ocean due to the lack of ship-based data that prohibited the constructions of surface carbon balance calculation, we presume that the proposed theoretical framework for Drake Passage would also work for the Indo-Pacific sector which are hot spots for upwelling of natural CO2 from Indo-Pacific Deep Water (Chen et al., 2022; Prend et al., 2022). It is reasonable that some discrepancies between ship- and float-derive pCO2 could be attributed to episodic or short-term (weekly to monthly) variabilities during the float observation (e.g., storms and mesoscale events) which would cause peaks in pCO2 (Kwak et al., 2021; Nicholson et al., 2022). However, our study reveals that the inconsistency existed throughout the observation on a longer timescale (yearly; Figure 6D). Furthermore, our study is also in line with some other studies applying novel techniques (Long et al., 2021; Mackay & Watson, 2021; Sutton et al., 2021; Wu et al., 2022) to indicate the possible overestimation of CO2 outgassing by SOCCOM floats which could be due to erroneous pH measurements or carbonate system-related biases (Álvarez et al., 2020; Wu et al., 2022).
Although it seems contradictory that Fay et al. (2018) and our study have used similar datasets (both used DPT and SOCCOM datasets) but came to different conclusions regarding the consistency between ship- and float-based pCO2 (Fay et al. claimed that the float-based pCO2 fall within the range of ship-based values given the uncertainty on the estimates), their study indeed revealed the overall higher float-based pCO2 than ship-based, particularly in winter, which is consistent with our findings. Fay et al. (2018) showed in their crossover analysis between ship- and float-based pCO2 in their Figure 9B equally large discrepancies and highly variable difference (i.e., large standard deviation). All of their findings consistently pointed to the fact that bias in float-based pCO2 is considerable. However, Fay et al. (2018) used a different averaging approach to obtain the final uncertainty value (grey box in their Figure 9B), during which process the overall uncertainty reduced to ±11 μatm, i.e., within the range of observational uncertainties as these authors argue. Noteworthy, ± 11 µatm is by no means an acceptable uncertainty range for the pCO2 observation, which is five times larger than the typical ship-based pCO2 uncertainty of ±2 µatm (Pierrot et al., 2009). In all cases, pCO2 is eventually used to calculate air-sea CO2 flux based on FCO2 = k×α×ΔpCO2, where k is CO2 gas transfer velocity, α is the CO2 solubility, and ΔpCO2 is the difference between sea surface and atmospheric level. Given that atmospheric pCO2 is stable and can be regarded as a constant at short timescale, the uncertainty of FCO2 would largely depend on the uncertainty of ΔpCO2, in their case this would cause ~180% uncertainty in FCO2 estimates and therefore cannot be ignored.
5 Conclusion
The autonomous biogeochemical-Argo floats have collected tremendous invaluable data to understand the global ocean carbon cycle, and made great efforts to fill the data gaps in the highly under-sampled Southern Ocean. Since the first few carbonate system studies from the SOCCOM project (Williams et al., 2017; Gray et al., 2018; Bushinsky et al., 2019) that revealed a striking CO2 outgassing signal due to upwelling in the high-latitude Southern Ocean (particularly in winter), there has been debates on the float-based data quality and the magnitude of float-derived Southern Ocean CO2 flux (e.g., Álvarez et al., 2020; Long et al., 2021; Mackay & Watson, 2021; Sutton et al., 2021; Wu et al., 2022). In this study, we chose the Drake Passage as a window of research to address the above issues, because it has been extensively observed by both ships and floats. We collected all ship-based pCO2 observations in Drake Passage during 2002-2017 and compared them with 8 series of float-based observations in the same region during 2014-2020. The detrended ship- and float-based pCO2 showed similar spatiotemporal patterns, however, a discrepancy of 14 µatm (float > ship) was found. We further applied an independent approach based on surface carbon balance to estimate the theoretical value of surface pCO2 if it was enhanced by upwelling, and suggested that upwelling is insufficient to cause the above discrepancy. These findings are against the previous statements (e.g., Fay et al., 2018) that float-based pCO2 fall within the range of ship-based values given the uncertainty on the estimates, although we both have found comparable deviations (averaged 14 µatm, with maximum of 24 µatm) to theirs (averaged 11 µatm, with maximum of 25 µatm). This is because the way that Fay et al. (2018) reported their results was based on relative uncertainty, therefore an uncertainty in pCO2 ± 2.7% (equivalent to ±11 µatm) would sound reasonable, although ±11 µatm is already five times larger than the general ship-based pCO2 uncertainty. We argue that more cautions have to be made in reporting/estimating the uncertainty, because essentially the ±2.7% pCO2 uncertainty would mean ~180% uncertainty in CO2 flux estimates.
Data availability statement
Publicly available datasets were analyzed in this study. This data can be found here: https://www.ldeo.columbia.edu/res/pi/CO2/; https://soccom.princeton.edu/.
Author contributions
Conceptualization, YW. Methodology, YW. Software, YW. Validation, DQ. Writing—original draft preparation, YW. Writing—review and editing, YW and DQ. All authors have read and agreed to the published version of the manuscript.
Funding
This study was funded by the Independent Research Projects of Southern Marine Science and Engineering Guangdong Laboratory (Zhuhai) (SML2021SP306), National Key Research and Development Program of China (2019YFE0114800, 2019YFC1509101), National Natural Science Foundation of China (42106222), Natural Science Foundation of Fujian Province, China (2020J05075, 2019J05148), and the Scientific Research Foundation of Ministry of Natural Resources (2019032).
Acknowledgments
We acknowledge the work by the data providers and scientists carrying out data collection, quality-control, and synthesis that led to the production of the datasets used here. We also sincerely thank the two reviewers for their constructive suggestions and comments.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s note
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Keywords: CO2 partial pressure, upwelling, CO2 outgassing, Drake Passage, Southern Ocean
Citation: Wu Y and Qi D (2022) Inconsistency between ship- and Argo float-based pCO2 at the intense upwelling region of the Drake Passage, Southern Ocean. Front. Mar. Sci. 9:1002398. doi: 10.3389/fmars.2022.1002398
Received: 25 July 2022; Accepted: 11 October 2022;
Published: 26 October 2022.
Edited by:
Gilles Reverdin, Centre National de la Recherche Scientifique (CNRS), FranceReviewed by:
Peter Landschützer, Max Planck Institute for Meteorology, Max Planck Society, GermanyAmanda Fay, Columbia University, United States
Copyright © 2022 Wu and Qi. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Di Qi, qidi@jmu.edu.cn