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Aquat Geochem DOI 10.1007/s10498-010-9111-2 ORIGINAL PAPER Effect of Dissolved Organic Carbon and Alkalinity on the Density of Arctic Ocean Waters Frank J. Millero • Fen Huang • Ryan J. Woosley • Robert T. Letscher Dennis A. Hansell • Received: 23 June 2010 / Accepted: 15 October 2010 Ó Springer Science+Business Media B.V. 2010 Abstract At constant temperature, the density of deep waters in the oceans is higher than that of surface waters due to the oxidation of plant material that adds NO3, PO4, and Si(OH)4, and the dissolution of CaCO3(s) that adds Ca2? and HCO3. These increases in the density have been used to estimate the absolute salinity of seawater that is needed to determine its thermodynamic properties. Density (q), total alkalinity (TA), and dissolved organic carbon (DOC) measurements were taken on waters collected in the eastern Arctic Ocean. The results were examined relative to the properties of North Atlantic Waters. The excess densities (Dq = qMeas - qCalc) in the surface Arctic waters were higher than expected (maximum of 0.008 kg m-3) when compared to Standard Seawater. This excess is due to the higher values of the normalized total alkalinity (NTA = TA * 35/S) (up to *2,650 lmol kg-1) and DOC (up to *130 lmol kg-1) resulting from river water input. New measurements are needed to determine how the DOC in the river waters contributes to the TA of the surface waters. The values of Dq in deep waters are slightly lower (-0.004 ± 0.002 kg m-3) than that in Standard Seawater. The deep waters in the Arctic Ocean, unlike the Atlantic, Pacific, Indian, and Southern Oceans, do not have significant concentrations of silicate (maximum *15 lmol kg-1) and that can affect the densities. Since the NTA of the deep Arctic waters (2,305 ± 6 lmol kg-1) is the same as Standard Seawater (2,306 ± 3 lmol kg-1), the decrease in the density may be caused by the lower concentrations of DOC in the deep waters (44–50 lmol kg-1 compared to the Standard Seawater value of 57 ± 2 lmol kg-1). The relative deficit of DOC (7–13 lmol kg-1) in the deep Arctic waters appears to cause the lower densities (-0.004 kg m-3) and Absolute Salinities (SA, -0.004 g kg-1). The effect of increases or decreases in Dq and dSA due to DOC in other deep ocean waters may be hidden in the correlations of the changes with silicate. Further work is needed to separate the effects of SiO2 and DOC on the density of deep waters of the world oceans. Keywords Dissolved organic carbon DOC Alkalinity Density Arctic Ocean F. J. Millero (&) F. Huang R. J. Woosley R. T. Letscher D. A. Hansell Rosenstiel School of Marine and Atmospheric Science, University of Miami, Miami, FL 33149, USA e-mail: [email protected] 123 Aquat Geochem 1 Introduction Although the composition of the major constituents of surface seawaters is relatively constant, the composition of deep waters can differ due to the oxidation of plant material adding NO3, PO4, and Si(OH)4 and the dissolution of CaCO3(s) increasing Ca2? and HCO3-. Brewer and Bradshaw (1975) and Millero (2000) have shown that these composition differences can affect the relationship between the measured conductivity Practical Salinity (SP) and physical properties such as density (q). Many of the thermodynamic properties of seawater, as well as other natural waters (lakes and estuaries), have been shown to be a function of the Absolute Salinity (SA) rather than the Practical Salinity (Millero 1974; Millero et al. 1976b). The physical chemical properties of natural waters are directly related to the composition of the major components, but not the salinity determined by conductivity. Non-electrolytes like Si(OH)4 and dissolved organic carbon (DOC), for example, do not have a large conductivity signal but can affect the physical properties of seawater. For this reason, the new Gibbs function for the thermodynamic properties of seawater (IAPWS 2008; Feistel 2008) is expressed as a function of Absolute Salinity rather than the Practical Salinity. The seawater used to determine the density (Millero and Poisson 1981), as well as other properties of seawater, was Atlantic surface waters of known Chlorinity. These Atlantic waters have low concentrations of nutrients and nearly constant total alkalinity (TA), total dissolved CO2 (TCO2) and dissolved organic carbon (DOC). Millero et al. (1998, 2008b) examined the composition of the North Atlantic surface waters used to calibrate salinometers (Standard Seawater) and to measure most of the physical chemical properties of seawater. They used the composition to determine the Reference Salinity (SR). For the range of salinities where Practical Salinities are defined ð2\SP \42Þ; SR is related to the Practical Salinity (SP) by SR ¼ ð35:16504=35ÞSP ; g kg1 ð1Þ Within the accuracy of present measurements, this reference composition is identical to that of Standard Seawater collected in a specific region of the North Atlantic. Millero et al. (2008b) estimated that the absolute uncertainty of SR is ±0.007 g kg-1. The difference between SR and SP (0.165 g kg-1) is much larger than the at-sea precision of measurements of SP (*0.003). This difference is related to the loss of boric acid and volatile salts during evaporation at 450°C (Millero 2006). The relationship of Practical Salinity Scale to Chlorinity (Cl) was defined by (Millero 2006) SP ¼ 1:80655 Cl ð2Þ This equation gives a value of SP = 35.000 when Cl = 19.374, the value for Standard Seawater used in many of the early physical chemical studies (Millero 2010). The Absolute Salinity of other waters in the oceans is related to the SR by SA ¼ SR þ dSA ð3Þ The correction dSA to the Reference Salinity SR is the sum of all the masses of the dissolved material added to deep waters (Millero et al. 2008b). Density measurements of seawaters by Millero et al. (1976a, b, 1978, 2008a, 2009; Millero 2000) were used to estimate the values of dSA for samples of seawater collected in the major oceans. The measured Practical Salinity SP and the differences in the density of seawater and pure water were measured on each sample at 25°C and atmospheric pressure (0 bars). The differences 123 Aquat Geochem in the measured and calculated densities from the equation of state of Millero and Poisson (1981) (Dq) were used to estimate the values of dSA dSA = g kg1 ¼ ðSA SR Þ= g kg1 ¼ Dq= kg m3 =0:7518 ð4Þ The 0.7518 kg m-3/(g kg-1) factor is determined from the partial derivative qq/qSA at 25°C and 1 atmosphere. Density measurements reported by Millero et al. (1976a, b, 1978, 2008a, 2009) indicated that the values of Dq and dSA were linear functions of the concentrations of Si(OH)4. Although changes in other nutrients and TA also showed a linear behavior, silicate was used because it displayed the best correlations, it is related to the other variables, it accounts for a significant fraction of the added material, and it is 90% non-ionic, thus having little effect on conductivity. McDougall et al. (2009) summarized all of the present 811 measurements and derived the equation for the world oceans ð5Þ dSA = g kg1 ¼ ðSA SR Þ= g kg1 ¼ 9:824 105 SiðOHÞ4 = lmol kg1 The standard error of the fit is 0.0054 g kg-1. This relationship was combined with global Si(OH)4 data to derive a relationship that can be used to estimate SA for many locations in the ocean (McDougall et al. 2009). It is assumed that these equations will be improved as more density measurements are made in other parts of the ocean. In the present paper, we present new density measurements made on waters collected in the Eastern Arctic Ocean. The effect of TA and DOC on the excess densities is examined. 2 Experimental Methods Samples were collected aboard the German icebreaker FS Polarstern during cruise ARKXXIII/3 (12 Aug. to 17 Oct., 2008). The cruise track circumnavigated the Arctic with extensive occupation of the western Chukchi/East Siberian Sea shelf break and adjacent Mendeleyev Ridge region. In addition, a transect crossing the Canada, Makarov, and Eurasian Basins at *80°N was occupied. Sea ice-free conditions were generally present south of 80°N in the study region with heavy ice conditions present to the north. Sampling was carried out through the ship’s hull-mounted seawater intake line at a depth of *10 m. Samples for TA, salinity, and density determinations were collected in 125-cm3 HDPE (high density polyethylene) bottles and sealed with parafilm until analyzed in the laboratory. Waters for DOC analysis were filtered inline between the Niskin bottles and 60-ml HDPE bottles and then stored frozen until analysis in the shore laboratory. Practical Salinities were measured with a Guildline Portasal salinometer calibrated with Standard Seawater (batch P31). It should be pointed out that the addition of Ca2? from the dissolution of CaCO3(s) causes very small changes in the measured Practical Salinity, SP. The densities were measured on a Paar 500 densimeter at 25.000 ± 0.003°C. Although the salinity was measured at sea, it was remeasured ashore at the same time as the densities were measured to account for any evaporation that may have occurred after collection. The relative density (q - q0) measurements of Standard Seawater were reproducible and agreed with those calculated from the equation of state (Millero and Poisson 1981) to r = 0.002 kg m-3. All of the measurements were taken relative to the density of pure water (q0) based on the equations of Kell (1975) and adjusted to the 1990 temperature scale (Spieweck and Bettin 1992). The densities for pure water from this equation are embedded 123 Aquat Geochem in the hardware of the Paar 500 densimeter. These relative densities are not strongly affected by changes in the temperature scale or the absolute value for the density of pure water used to calibrate the densimeter. Measurements taken on Standard Seawater (P146) of known Practical Salinity yielded densities at 25°C that agreed with the equation of state to within r = 0.003 kg m-3, which is the precision of the measurements. The excess densities (Dq = qMeas - qCalc) were determined by comparing the measured values to those determined from the equation of state of seawater (Millero and Poisson 1981). TA measurements were taken using methods developed by Millero et al. (1993). The titration system was calibrated using seawater of known TA (provided by Dr. Andrew G. Dickson, UCSD-SIO-Marine Physical Laboratory) and had a precision of ±2 lmol kg-1. DOC measurements were taken by high-temperature combustion using the methods of Farmer and Hansell (2007), with a precision of 2 lmol kg-1. DOC in Standard Seawater collected in the North Atlantic was 57.2 ± 2 lmol kg-1 and NTA was 2,306 ± 3 lmol kg-1. The surface layer data considered here exhibited little dilution by sea ice melt, as assessed by d18O measurements and as reported by Letscher et al. (2010). 3 Results Salinity (SP), TA, DOC, and excess density (Dq = qMeas - qCalc) were determined for all the Arctic seawaters returned to the laboratory. The hydrographic data and the laboratory measurements, as a function of location and depth, are tabulated in Table 1, and the surface values are compiled in Table 2. NTA results are shown as a function of depth in Fig. 1. All of the deep waters have NTA of 2,305 ± 6 lmol kg-1, similar to the values for Standard Seawater of 2,306 ± 3 lmol kg-1 collected in the North Atlantic. The surface values increase to concentrations as high as 2,650 lmol kg-1. Dissolved organic carbon (DOC) concentrations are shown as a function of depth in Fig. 2. The deep waters below 150 m have values between 44 (the deep Arctic basin waters) and 51 lM (the Atlantic water layer), which are lower by 6–13 lmol kg-1 than the values in North Atlantic Standard Seawater (57.2 ± 2 lmol kg-1). The surface water DOC concentrations are as high as 130 lmol kg-1, much higher than surface waters in other oceans (commonly \80 lmol kg-1; Hansell et al. 2009). The surface distributions of NTA and DOC at 10 m depth are shown in Figs. 3 and 4. The high values of NTA and DOC originate from Arctic rivers (Anderson et al. 2004; Letscher et al. 2010). The measured excess densities Dq/(kg m-3) = qmeas - qcalc are shown as a function of depth in Fig. 5. The deep waters have values of Dq = -0.004 ± 0.002 kg m-3, while the surface waters have values as high as Dq = 0.008 ± 0.002 kg m-3. 4 Discussion Unlike other oceans, the deep waters of the Arctic have values of Dq that are negative. Most deep ocean waters have positive values of Dq due to the addition of nutrients and calcium carbonate. Determinations of nutrients in Arctic deep water are sparse and concentrations are very low compared with most other deep ocean waters. The silicate concentrations, for example, have maximum values in deep water of *15 lmol kg-1 (Middag et al. 2009). Based upon our work in other oceans, this Si concentration will increase the 123 Aquat Geochem Table 1 Measurements of alkalinity, dissolved organic carbon, and excess density for waters in the Arctic Ocean as a function of depth LAT. o N LONG. E o Depth dbar Temp C o TA lmol kg-1 SP NTA lmol kg-1 DOC lmol kg-1 Dq kg m-3 80.46 -158.68 3.6 -1.617 2,104 30.208 2,437 67.7 0.000 80.46 -158.68 30.1 -1.504 2,218 31.810 2,440 66.8 0.000 80.46 -158.68 80.46 -158.68 -1.611 2,213 31.992 2,421 66.2 0.002 101 49.8 -1.561 2,244 32.591 2,410 61.0 -0.005 80.46 -158.68 201.7 -0.909 2,271 34.346 2,314 58.5 -0.006 80.46 -158.68 303.2 0.468 2,282 34.756 2,298 53.7 -0.005 80.46 -158.68 506 80.46 -158.68 1,013.8 0.792 2,293 34.864 2,302 49.6 -0.006 -0.049 2,297 34.932 2,302 48.4 -0.004 80.46 -158.68 2,031.4 -0.408 2,300 34.950 2,304 43.6 -0.006 80.46 -158.68 3,054 -0.329 2,306 34.955 2,309 43.2 -0.002 80.58 -162.40 3.5 -1.611 2,118 30.338 2,443 66.6 0.006 80.58 -162.40 10.1 -1.613 2,119 30.446 2,436 66.2 0.002 80.58 -162.40 50.5 -1.611 2,216 32.081 2,418 63.4 0.004 80.58 -162.40 101.4 -1.617 2,231 32.668 2,391 60.5 0.001 80.58 -162.40 202.4 -0.880 2,276 34.345 2,319 58.4 -0.005 80.58 -162.40 303.3 0.402 2,279 34.730 2,296 50.6 -0.006 -0.006 80.58 -162.40 506 0.544 2,284 34.865 2,293 48.3 80.58 -162.40 1,013.2 -0.126 2,290 34.894 2,297 48.8 -0.005 80.58 -162.40 2,031.3 -0.416 2,293 34.951 2,297 44.0 -0.006 2,592.7 -0.005 80.58 -162.40 -0.365 2,298 34.960 2,301 43.9 80.55 -174.69 4 -1.639 2,123 30.633 2,425 67.9 0.001 80.55 -174.69 29.9 -1.544 2,229 32.149 2,426 68.5 0.000 80.55 -174.69 50.4 -1.653 2,222 32.332 2,405 65.2 0.000 80.55 -174.69 99.8 -1.484 2,246 33.055 2,379 61.5 0.000 80.55 -174.69 202.2 -0.460 2,284 34.490 2,318 56.6 -0.002 80.55 -174.69 303.6 0.685 2,294 34.807 2,306 51.0 -0.004 80.55 -174.69 505.8 0.710 2,289 34.862 2,298 52.6 -0.006 80.55 -174.69 1,013.2 -0.122 2,289 34.880 2,297 46.8 -0.007 80.55 -174.69 2,031.2 -0.411 2,295 34.965 2,297 40.8 -0.001 80.55 -174.69 2,553.4 -0.368 2,310 35.000 2,310 40.8 -0.004 80.39 178.71 9.8 -1.597 2,091 30.249 2,420 69.8 -0.001 80.39 178.71 40.4 -1.642 2,237 32.412 2,415 64.6 -0.002 80.39 178.71 101.1 -1.362 2,250 33.586 2,345 63.5 -0.004 80.39 178.71 202.2 -0.231 2,277 34.535 2,308 57.1 -0.002 80.39 178.71 303.6 0.965 2,283 34.811 2,295 52.3 -0.005 80.39 178.71 405 0.909 2,292 34.836 2,303 51.4 -0.005 80.39 178.71 506.3 0.781 2,300 34.850 2,310 51.8 -0.005 80.39 178.71 759.4 0.261 2,292 34.861 2,301 50.6 -0.004 80.39 178.71 1,012.9 -0.105 2,291 34.869 2,300 50.7 -0.001 80.56 175.74 3.5 -1.521 1,957 28.102 2,437 76.0 0.000 80.56 175.74 29.5 -1.308 2,176 31.472 2,420 71.1 0.005 80.56 175.74 50.2 -1.551 2,222 32.818 2,369 64.9 0.003 123 Aquat Geochem Table 1 continued LAT. o N LONG. E o Depth dbar Temp C TA lmol kg-1 SP NTA lmol kg-1 o DOC lmol kg-1 Dq kg m-3 80.56 175.74 100.9 -1.330 2,281 34.140 2,338 63.1 0.002 80.56 175.74 202.3 0.326 2,282 34.643 2,306 53.7 0.002 80.56 175.74 303.3 0.950 2,293 34.824 2,305 51.0 0.001 80.56 175.74 555.8 0.611 2,290 34.869 2,298 50.0 -0.004 80.56 175.74 1,013.6 -0.148 2,299 34.870 2,308 51.3 -0.005 80.56 175.74 2,031.6 -0.410 2,294 34.954 2,297 42.8 -0.005 80.56 175.74 2,530.6 -0.369 2,308 34.966 2,310 40.0 -0.003 81.00 164.87 3.7 -1.490 1,966 27.601 2,494 111.0 0.002 81.00 164.87 10.1 -1.487 1,967 27.702 2,485 105.8 0.002 81.00 164.87 50.5 -1.550 2,247 33.605 2,340 72.4 0.001 81.00 164.87 101.3 -1.169 2,287 34.318 2,332 61.7 -0.001 81.00 164.87 202.7 0.684 2,294 34.743 2,311 51.5 -0.003 81.00 164.87 304.3 1.008 2,290 34.846 2,301 50.7 -0.004 81.00 164.87 507.2 0.619 2,295 34.867 2,303 50.6 -0.002 81.00 164.87 1,015.8 -0.221 2,297 34.881 2,305 50.3 -0.005 81.00 164.87 2,031.5 -0.408 2,308 34.945 2,312 42.5 -0.003 81.00 164.87 2,742.3 -0.353 2,303 34.959 2,306 42.2 -0.001 81.02 145.04 3.5 -1.737 2,172 31.848 2,387 81.02 145.04 10.3 -1.738 2,186 31.903 2,399 89.1 0.001 -0.001 0.002 81.02 145.04 50.5 -1.643 2,270 33.966 2,339 69.1 81.02 145.04 101.5 -1.009 2,290 34.447 2,326 61.1 0.000 81.02 145.04 152.3 -0.198 2,282 34.638 2,306 57.7 -0.004 81.02 145.04 303.8 0.972 2,298 34.848 2,308 53.6 -0.004 81.02 145.04 760.2 -0.029 2,299 34.869 2,308 51.0 -0.005 81.02 145.04 1,522.2 -0.467 2,285 34.915 2,291 46.7 -0.003 80.97 142.08 10.4 -1.750 2,171 32.013 2,374 88.5 -0.001 80.97 142.08 50.7 -1.597 2,265 33.739 2,350 70.5 -0.001 80.97 142.08 101.4 -1.042 2,281 34.430 2,318 58.3 -0.004 80.97 142.08 202.6 0.804 2,290 34.781 2,305 52.2 -0.004 80.97 142.08 407.6 0.884 2,288 34.883 2,296 51.8 -0.005 80.97 142.08 1,012.4 -0.247 2,292 34.888 2,299 47.0 -0.004 -0.004 80.97 142.08 1,584.8 -0.435 2,299 34.998 2,299 43.2 80.98 139.01 10.3 -1.750 2,195 32.138 2,391 85.0 0.001 80.98 139.01 50.8 -1.664 2,276 33.958 2,346 65.8 -0.004 80.98 139.01 101.3 -0.859 2,280 34.488 2,314 56.3 -0.004 80.98 139.01 253.1 1.236 2,295 34.871 2,304 51.8 -0.005 80.98 139.01 505.6 0.514 2,291 34.879 2,299 51.8 -0.003 80.98 139.01 1,013.4 -0.232 2,299 34.888 2,306 52.4 -0.005 80.98 139.01 1,667.8 -0.533 2,309 34.946 2,313 44.6 -0.004 81.01 136.11 3.7 -1.742 2,196 32.138 2,392 92.0 0.002 81.01 136.11 10.1 -1.745 2,205 32.144 2,401 91.7 0.000 81.01 136.11 49.1 -1.704 2,264 33.674 2,353 71.2 -0.001 123 Aquat Geochem Table 1 continued LAT. o N LONG. E o Depth dbar Temp C TA lmol kg-1 o SP NTA lmol kg-1 DOC lmol kg-1 Dq kg m-3 81.01 136.11 101.3 -0.902 2,300 34.472 2,335 56.5 -0.005 81.01 136.11 202.3 1.519 2,297 34.860 2,306 49.3 -0.005 81.01 136.11 404.8 1.300 2,312 34.911 2,318 48.0 -0.004 81.01 136.11 1,013.1 -0.265 2,304 34.907 2,310 48.6 -0.002 81.01 136.11 2,541.8 -0.768 2,307 34.932 2,311 44.1 -0.003 81.24 121.27 3.4 -1.778 2,231 32.992 2,367 79.0 0.000 81.24 121.27 10.3 -1.780 2,241 33.088 2,371 77.1 0.001 81.24 121.27 50.4 -1.757 2,284 33.824 2,364 74.0 0.003 81.24 121.27 101.1 -0.602 2,277 34.377 2,319 57.5 -0.001 81.24 121.27 202.4 1.707 2,296 34.882 2,304 49.9 -0.002 81.24 121.27 303.2 1.424 2,295 34.891 2,302 48.7 -0.002 81.24 121.27 505.9 0.835 2,296 34.906 2,303 47.6 -0.003 81.24 121.27 1,013.1 -0.326 2,296 34.907 2,302 48.4 -0.001 81.24 121.27 2,031.5 -0.760 2,308 34.929 2,312 45.0 -0.002 81.24 121.27 3,054.1 -0.760 2,301 34.944 2,305 43.8 -0.003 81.24 121.27 4,260.4 -0.640 2,307 34.948 2,310 43.0 -0.002 Table 2 Measurements of alkalinity, dissolved organic carbon, and excess density for surface water (*10 m) in the Arctic Ocean LAT. o N LONG. o E Temp C o SP TA lmol/kg NTA lmol/kg DOC lmol/kg Dq kg m-3 74.92 -127.00 -1.28 27.601 1,941.3 2,461.8 60.5 0.002 74.86 -128.38 -1.01 27.425 1,929.6 2,462.6 60.7 -0.003 74.81 -129.76 -1.01 27.057 1,911.5 2,472.7 61.5 0.004 74.78 -129.39 -0.94 26.656 1,887.7 2,478.6 63.9 0.005 74.80 -130.67 -0.93 26.261 1,868.7 2,490.5 64.9 0.006 74.82 -131.25 -0.91 24.448 1,769.0 2,532.5 64.7 0.005 69.50 -136.01 6.07 24.237 1,750.7 2,528.1 89.4 0.007 73.34 -141.23 4.64 22.886 1,681.6 2,571.7 61.9 0.006 74.49 -147.17 3.11 22.891 1,670.4 2,554.0 60.6 0.004 75.17 -151.39 3.67 22.859 1,673.4 2,562.2 61.8 0.003 75.87 -155.32 1.92 24.227 1,761.2 2,544.3 61.4 0.003 76.93 -162.98 -0.83 24.340 1,766.9 2,540.7 59.6 0.004 77.09 -163.86 -0.73 24.771 1,785.0 2,522.1 59.1 0.003 77.47 -165.31 -0.83 26.129 1,867.8 2,501.9 59.5 0.002 77.95 -169.77 -1.04 26.220 1,858.8 2,481.3 58.3 0.004 78.00 -170.09 -1.19 26.143 1,858.2 2,487.7 59.6 0.002 78.11 -173.04 -1.02 28.947 2,029.2 2,453.5 62.8 0.003 78.23 -178.68 -1.55 29.137 2,029.2 2,437.5 61.6 0.002 78.23 179.17 -1.59 30.544 2,122.2 2,431.8 67.1 0.002 78.07 178.47 -1.62 30.541 2,117.9 2,427.2 64.6 -0.004 123 Aquat Geochem Table 2 continued LAT. o N LONG. E o Temp C o SP TA lmol/kg NTA lmol/kg DOC lmol/kg Dq kg m-3 -0.001 78.15 177.47 -1.61 30.549 2,090.0 2,394.5 66.1 78.41 173.93 -1.55 30.586 2,117.8 2,423.4 64.1 0.003 78.47 173.00 -1.52 30.592 2,117.1 2,422.1 64.3 -0.002 78.19 172.73 -1.6 29.834 2,065.3 2,422.9 67.8 0.001 77.97 173.05 -1.65 30.430 2,099.9 2,415.2 66.9 0.002 77.60 177.07 -1.29 30.847 2,124.2 2,410.2 65.3 0.001 77.60 179.66 -1.27 30.185 2,081.2 2,413.1 67.5 0.001 77.60 -177.77 -1.36 30.084 2,077.2 2,416.7 64.8 0.003 77.59 -172.16 -0.88 30.101 2,079.1 2,417.5 63.7 0.001 77.59 -171.34 -0.99 30.343 2,097.0 2,418.9 65.0 -0.002 77.58 -170.48 -0.87 28.773 2,027.1 2,465.8 75.1 -0.001 77.59 -170.46 -0.86 28.801 2,015.4 2,449.2 66.1 0.003 77.62 -175.86 -0.98 28.830 2,008.8 2,438.8 68.4 0.004 77.60 -176.66 -0.98 28.800 2,018.4 2,452.9 62.3 0.001 77.51 -178.68 -1.22 30.214 2,090.1 2,421.2 70.5 0.001 -0.004 77.24 178.58 -0.84 30.161 2,090.8 2,426.2 70.1 77.31 179.05 -0.76 30.163 2,085.7 2,420.2 67.8 0.001 77.61 174.54 -1.41 30.236 2,088.6 2,417.7 68.6 0.000 77.34 174.14 -0.91 30.829 2,123.5 2,410.8 67.5 0.002 77.06 173.71 -0.85 30.840 2,126.2 2,413.0 70.0 -0.003 76.78 173.29 -1.02 30.471 2,103.4 2,416.0 72.8 0.000 76.47 172.85 -0.74 30.476 2,103.3 2,415.5 71.5 0.001 76.23 172.51 -0.65 30.486 2,107.1 2,419.1 73.3 0.001 75.98 172.16 -1.12 30.488 2,103.4 2,414.7 73.5 0.001 75.72 171.80 -1.44 30.422 2,093.9 2,409.0 73.5 0.000 75.51 171.50 -1.49 30.373 2,093.0 2,411.8 67.5 -0.002 75.25 170.98 -1.27 30.200 2,076.2 2,406.2 63.9 0.001 74.72 170.94 -1.28 29.383 2,032.8 2,421.4 71.2 0.005 74.79 171.57 -1.18 29.377 2,030.0 2,418.5 70.2 0.002 74.86 172.18 -0.88 29.391 2,028.4 2,415.6 67.5 0.002 74.92 172.83 -0.8 29.414 2,027.9 2,413.0 68.1 0.004 75.05 173.33 -0.36 30.138 2,081.2 2,417.0 67.3 0.003 75.05 173.99 -0.27 30.208 2,082.0 2,412.2 64.1 0.002 75.36 177.20 0.05 30.278 2,088.0 2,413.6 62.6 0.002 75.42 177.81 0.02 30.099 2,090.6 2,431.0 68.3 0.004 75.49 178.46 0.13 30.135 2,100.8 2,439.9 70.9 0.003 75.55 179.09 -0.37 30.112 2,095.0 2,435.1 67.1 0.001 75.61 179.72 -0.51 28.934 2,030.4 2,456.1 66.1 0.001 75.67 -178.33 -0.68 28.349 1,998.8 2,467.8 67.1 0.005 75.74 -177.02 -0.75 28.296 2,004.0 2,478.8 66.8 0.003 75.80 -177.63 -0.9 28.256 1,994.0 2,469.9 66.2 0.001 76.13 -174.87 -1.04 27.507 1,945.5 2,475.4 62.5 0.007 123 Aquat Geochem Table 2 continued LAT. o N LONG. E o Temp C o SP TA lmol/kg NTA lmol/kg DOC lmol/kg Dq kg m-3 76.18 -173.56 -0.9 27.381 1,929.3 2,466.1 64.3 0.004 76.28 -172.13 -1.05 27.411 1,939.0 2,475.8 63.6 0.001 76.29 -172.83 -0.85 27.402 1,939.8 2,477.6 63.3 0.001 76.35 -171.49 -0.86 27.412 1,939.8 2,476.8 62.4 0.002 76.40 -170.14 -0.74 27.374 1,939.7 2,480.0 63.4 0.004 76.34 -170.78 -0.68 26.687 1,896.5 2,487.3 64.3 0.002 76.32 -169.40 -0.68 26.541 1,890.2 2,492.6 63.2 0.001 76.28 -165.15 1.07 26.195 1,856.8 2,481.0 60.1 0.003 75.98 -165.76 3.01 25.655 1,829.0 2,495.2 60.6 0.001 75.86 -165.83 2.99 25.663 1,832.4 2,499.0 60.7 0.001 75.72 -165.73 2.82 25.621 1,830.8 2,501.0 62.0 0.002 75.54 -165.71 2.8 25.623 1,831.7 2,502.0 63.6 0.002 74.57 -165.60 2.66 25.965 1,864.5 2,513.3 67.7 0.005 74.26 -165.56 3.04 25.756 1,843.1 2,504.6 68.6 0.005 73.93 -165.53 2.49 25.752 1,843.2 2,505.1 68.8 0.006 73.63 -165.49 0.28 25.764 1,842.3 2,502.8 67.5 0.005 73.85 -165.17 2.93 26.602 1,852.4 2,437.2 66.3 0.005 74.65 -167.69 2.65 26.365 1,853.4 2,460.4 63.5 0.005 74.84 -167.32 1.48 25.937 1,843.5 2,487.6 70.7 0.006 75.05 -168.93 1.92 25.959 1,863.6 2,512.7 67.8 0.005 75.04 -168.84 1.85 26.215 1,878.5 2,508.0 64.6 0.005 75.24 -168.55 1.39 26.207 1,863.0 2,488.0 64.6 0.006 75.39 -168.05 0.39 25.997 1,855.5 2,498.0 64.0 0.005 75.59 -169.82 26.044 1,863.5 2,504.4 62.6 0.005 -0.5 76.39 -171.81 -0.76 25.479 1,825.1 2,507.2 60.1 0.006 76.45 -172.71 -1.07 26.047 1,844.3 2,478.3 60.5 0.005 76.50 -173.84 -0.95 27.161 1,921.7 2,476.3 63.1 0.002 76.45 -174.62 -1.03 27.137 1,919.0 2,475.0 64.0 0.003 76.42 -175.48 -0.93 27.012 1,921.2 2,489.3 62.1 0.005 76.46 178.13 -0.08 29.733 2,073.2 2,440.5 68.1 0.006 75.33 174.75 -0.07 30.186 2,090.2 2,423.5 68.6 0.000 75.13 175.35 0.24 29.852 2,067.4 2,423.9 69.3 0.001 75.11 175.36 0.17 29.439 2,048.1 2,435.0 68.6 0.001 75.31 176.25 0.13 29.727 2,068.5 2,435.4 65.1 0.004 75.44 176.85 0.13 29.979 2,082.9 2,431.7 67.4 0.000 75.57 177.48 -0.16 28.948 2,029.7 2,454.0 65.0 0.002 75.84 178.76 0.01 29.602 2,064.5 2,440.9 66.4 0.001 76.15 -178.07 -0.18 29.207 2,049.8 2,456.4 67.6 0.002 76.48 -178.52 -0.14 29.456 2,056.2 2,443.3 67.1 0.002 76.75 -178.91 -0.21 29.769 2,073.9 2,438.3 66.9 0.001 77.05 -177.36 -0.23 29.475 2,058.9 2,444.8 66.9 0.002 77.01 -173.64 -0.66 28.893 2,034.9 2,465.0 66.2 0.004 123 Aquat Geochem Table 2 continued LAT. o N LONG. E o Temp C o SP TA lmol/kg NTA lmol/kg DOC lmol/kg Dq kg m-3 77.06 -172.69 -0.72 28.629 2,009.0 2,456.0 65.0 0.004 77.06 -171.91 -1.02 27.004 1,930.1 2,501.6 54.4 0.003 77.16 -170.78 -0.99 26.646 1,890.2 2,482.8 62.5 0.002 77.63 -170.47 -1.04 27.673 1,955.6 2,473.4 64.0 0.006 79.20 -165.45 -1.46 29.331 2,051.3 2,447.7 65.5 0.002 79.51 -163.24 -1.49 29.281 2,045.7 2,445.2 66.3 0.003 79.76 -162.89 -1.55 29.457 2,057.2 2,444.3 64.2 0.004 80.09 -160.81 -1.61 30.090 2,097.9 2,440.2 69.0 0.003 80.29 -159.99 -1.57 30.162 2,103.7 2,441.2 71.3 0.002 80.60 -156.76 -1.56 29.956 2,088.5 2,440.2 64.7 0.000 80.72 -154.50 -1.5 29.900 2,086.0 2,441.8 63.5 0.002 80.57 -162.38 -1.58 30.213 2,103.0 2,436.2 65.0 0.004 80.64 -165.29 -1.45 30.380 2,084.2 2,401.1 64.8 0.003 80.62 -167.92 -1.57 30.303 2,107.1 2,433.7 63.6 0.004 80.59 -168.69 -1.45 30.267 2,107.6 2,437.1 73.5 0.000 80.62 -168.15 -1.51 30.425 2,118.1 2,436.6 55.9 0.001 80.69 -170.45 -1.61 30.346 1,937.6 2,463.0 72.5 0.002 80.56 -171.21 -1.61 30.356 2,108.7 2,431.2 70.6 0.004 80.38 -176.65 -1.59 30.657 2,123.9 2,424.8 71.0 0.004 80.32 -177.35 -1.58 30.640 2,122.6 2,424.6 70.0 -0.001 80.31 -177.45 80.39 178.69 -1.65 30.746 2,127.8 2,422.2 71.3 0.002 -1.6 29.973 2,076.2 2,424.4 70.7 0.000 -0.001 80.51 176.70 -1.46 28.482 1,982.4 2,436.0 80.2 80.54 173.77 -1.53 28.252 19,76.8 2,448.9 77.1 0.000 80.59 172.10 -1.51 28.210 1,968.5 2,442.3 79.8 -0.001 80.37 172.13 -1.5 28.270 1,969.9 2,438.9 79.8 0.002 80.87 167.62 -1.47 27.528 1,976.4 2,512.8 117.5 0.001 80.94 166.13 -1.49 27.482 1,967.5 2,505.7 118.9 0.000 81.00 158.73 -1.49 27.608 1,990.5 2,523.5 129.4 0.002 81.00 157.06 -1.44 26.586 1,925.2 2,534.5 124.0 0.002 81.00 155.42 -1.5 27.672 1,980.1 2,504.5 120.2 0.000 81.00 153.87 -1.53 28.319 2,015.8 2,491.4 119.1 0.003 81.00 151.97 -1.56 28.792 2,049.8 2,491.7 120.4 0.007 80.98 148.00 -1.74 32.298 2,220.0 2,405.7 91.6 0.004 80.99 146.47 -1.7 32.091 2,188.1 2,386.4 85.6 -0.002 81.05 140.57 -1.65 31.939 2,179.6 2,388.4 86.6 -0.003 80.98 137.54 -1.72 32.006 2,207.6 2,414.1 94.8 -0.003 -0.003 81.01 136.09 -1.7 32.135 2,212.5 2,409.8 91.5 81.17 128.79 -1.53 31.444 2,166.9 2,411.9 101.5 0.005 81.16 127.93 -1.42 31.371 2,167.9 2,418.6 100.9 0.005 81.10 126.61 -1.62 31.359 2,167.2 2,418.8 101.1 0.002 81.12 124.42 -1.57 31.464 2,165.7 2,409.1 98.8 0.001 123 Aquat Geochem Table 2 continued LAT. o N LONG. E Temp C o TA lmol/kg SP o NTA lmol/kg Dq kg m-3 DOC lmol/kg 81.16 123.10 -1.66 32.040 2,191.3 2,393.8 90.7 0.001 81.24 121.22 -1.79 32.968 2,229.3 2,366.7 78.6 0.000 80.48 121.48 -1.68 32.852 2,220.2 2,365.3 76.0 0.000 80.22 120.86 -1.73 32.951 2,219.2 2,357.2 73.6 -0.003 79.95 119.95 -1.74 33.040 2,220.7 2,352.4 71.0 -0.002 79.65 118.87 -1.69 32.623 2,192.0 2,351.8 70.1 -0.003 79.46 118.55 -1.69 32.214 2,181.3 2,370.0 77.6 -0.003 79.24 118.11 -1.69 32.258 2,181.4 2,366.8 79.8 -0.002 78.54 117.77 -1.65 31.284 2,130.9 2,384.0 91.4 -0.002 78.21 117.30 -1.64 30.251 2,072.7 2,398.0 95.6 -0.001 77.95 116.64 -1.57 29.899 2,067.7 2,420.5 98.8 0.001 77.92 115.22 -1.48 29.844 2,077.0 2,435.8 102.6 0.003 77.91 114.00 -1.59 29.769 2,083.5 2,449.6 105.8 0.001 NTA , μmol kg-1 2200 0 2300 2400 2500 2600 2700 1000 Depth, db 2000 3000 4000 5000 Fig. 1 Normalized total alkalinity (NTA = 35 TA/S) as a function of depth in the Arctic Ocean 123 Aquat Geochem DOC, μmol kg-1 20 0 40 60 80 100 120 140 1000 Depth, db 2000 3000 4000 5000 Fig. 2 Dissolved organic carbon (DOC) as a function of depth in the Arctic Ocean Fig. 3 Distribution of normalized total alkalinity (NTA, lmol/kg) for surface waters in the Arctic Ocean density by 0.001 kg m-3, which is within the experimental error of our measurements. Since the values of NTA are the same as Standard Seawater, the decrease cannot be attributed to lower TA values. It appears that the decrease in density of the deep Arctic may be caused by the slightly lower DOC concentrations (44–51 lmol kg-1) below 150 m 123 Aquat Geochem Fig. 4 Distribution of dissolved organic carbon (DOC, lmol/kg) for surface waters in the Arctic Ocean Δ ρ, kg m -0.008 0 -0.006 -0.004 -0.002 0.000 -3 0.002 0.004 0.006 0.008 Depth, db 1000 2000 3000 4000 5000 Fig. 5 Values of (q - q0) as a function of depth in the Arctic Ocean compared with the Standard Seawater value of 57 ± 2 lmol kg-1. Since the maximum changes in DOC concentration from the surface to depth in the open ocean are *30 lmol kg-1 (Hansell et al. 2009), one might estimate that the effect of DOC in the 123 Aquat Geochem 2800 Eastern Basin Western Basin NTA, μmol kg -1 2700 2600 2500 2400 2300 2200 24 26 28 30 32 34 Practical Salinity, SP Fig. 6 NTA as a function of the salinity for surface waters in the eastern and western Arctic Ocean 140 Eastern Basin Western Basin DOC, μmol kg-1 120 100 80 60 40 26 27 28 29 30 31 32 33 34 Salinity Fig. 7 DOC as a function of salinity for surface waters in the eastern and western Arctic Ocean world ocean waters could be as much 0.012 kg m-3. This is unfortunately very difficult to prove at the present time. The Dq values for most of the surface waters have positive values. These elevated densities can be attributed to the higher concentrations of NTA and DOC from the input of river waters to the Arctic (Anderson et al. 2004; Hansell et al. 2004). Evidence for this is shown in plots of all measured surface NTA as a function of salinity in Fig. 6. As shown elsewhere (Amon 2004; Letscher et al. 2010), DOC displays a linear behavior as a function of salinity near the major river inputs (Fig. 7). Figures 6 and 7 also give previously reported values of NTA (Bates et al. 2009) and DOC (Hansell et al. 2004) for surface waters in the western Arctic Ocean. At a given salinity, the values of NTA are lower and DOC is higher in the eastern sector of the Arctic compared with the western sector. The differences in NTA are due to the differences in NTA concentrations between eastern and western Arctic rivers (Cooper et al. 2008), while the differences in DOC are due to both differences in riverine concentrations (Cooper et al. 2008) and in the greater DOC removal 123 Aquat Geochem 140 Eastern Basin Western Basin DOC, μmol kg -1 120 100 80 60 40 2300 2350 2400 2450 2500 2550 2600 2650 -1 NTA, μmol kg Fig. 8 Correlation of the values of DOC and NTA for waters in the eastern and western Arctic Ocean in the western sector (Hansell et al. 2004; Letscher et al. 2010). As shown in Fig. 8, the values of DOC and NTA in this region correlate very well with one another. At an NTA around 2,300 lmol kg-1, the values of DOC are near 60 lmol kg-1, similar to Standard Seawater from the North Atlantic. At the present time, it is not possible to determine how much of the NTA from the rivers is due to organic compounds that can accept a proton. An over determination of pCO2 or pH with TA and TCO2 in Arctic estuaries may allow one to estimate the contribution of increases in TA due to organic compounds. This is also true of other estuarine systems that contribute alkalinity to the world oceans. Acknowledgments The authors wish to acknowledge the Ocean Sciences section of the US National Science Foundations for supporting our studies. FJM also wishes to acknowledge the support of the National Oceanic and Atmospheric Administration. DAH and RL were supported by NSF OPP-0822429 and NSF OPP-0732082. FJM is saddened by the sudden death of Dr. John Morse. He has been a longtime scientific and personal colleague that will be missed by all of the scientific community. References Amon RMW (2004) The role of dissolved organic matter for the organic carbon cycle in the Arctic Ocean. In: Stein R, Macdonald RW (eds) The organic carbon cycle in the Arctic Ocean. 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