Abstract
Coastal Oyashio Water (COW), defined as a water mass with a temperature lower than 2 °C and a salinity lower than 33.0, is distributed in the North Pacific Ocean off southeastern Hokkaido, Japan, from winter to spring. COW is rich in macronutrients and dissolved iron and is thus considered to affect the spring phytoplankton blooms in the Oyashio region. Although river water and sea-ice melt water have been considered freshwater end-members of COW, the contributions of these freshwater sources to COW have not been well described. In this study, the humic-like components in dissolved organic matter were first applied as a parameter to evaluate the freshwater end-members of COW in March 2015. Linear regressions with negative slopes were determined between the humic-like components and the salinity of COW. The intercepts of the regressions against the humic-like components were within the ranges of those observed for the local rivers of Hokkaido but were very different from those of sea ice. These findings suggest that river water contributed to the COW observed here as a freshwater end-member, although the contribution of sea-ice melt water to COW could not be evaluated. This novel approach also highlighted two different less-saline water masses in COW. The first was characterized by a lower temperature and relatively high levels of humic-like components, while the second was higher in temperature and had higher levels of humic-like components. It is suggested that these different characteristics are due to the contributions of water from different rivers and/or different effects of sea-ice melt water.
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1 Introduction
Riverine humic substances can be considered one of the major components of dissolved organic matter (DOM) in coastal environments because linear negative correlations between the salinity and dissolved organic carbon (DOC) concentration as well as the fluorescence derived from terrestrial humic substances have often been observed (Fellman et al. 2010; Yamashita et al. 2011; 2015a; Cao et al. 2016). These negative correlations also suggest that the fluorescence intensity of terrestrial humic substances (in other words, the levels of terrestrial humic fluorophores) can be used as a tracer of river water, similar to the oxygen isotopes of water or alkalinity (e.g., Yamamoto-Kawai et al. 2009). However, it should be noted that marine organisms, in particular bacteria, produce humic-like fluorophores (e.g., Romera-Castillo et al. 2011; Goto et al. 2017; Arai et al. 2018), sunlight degrades humic-like fluorophores (e.g., Moran et al. 2000; Vähätalo and Wetzel 2004), and the levels of humic-like fluorophores in river water show temporal variability (e.g., Austnes et al. 2010; Chen et al. 2013; Walker et al. 2013). Thus, the relationship between salinity and humic-like fluorophores has generally been used to evaluate the abovementioned environmental dynamics of humic fluorophores (including autochthonous humic-like fluorophores), rather than to trace the river water in coastal environments (e.g., Vodacek et al. 1997; Yamashita et al. 2008; Cawley et al. 2014; Maie et al. 2014).
Chen and Gardner (2004) observed conservative mixing of humic fluorophores between various freshwater and marine end-members with significant in situ microbial production, evidence of flocculation, and minor photobleaching effects in the Mississippi and Atchafalaya river plume regions using in situ fluorescence sensors. Previous studies carried out in the Arctic Ocean have indicated that humic-like fluorophores can be used to trace river water (Amon et al. 2003; Walker et al. 2009; Gonçalves-Araujo et al. 2016) and to separate the distributions of two different freshwater sources, i.e., river water and sea-ice melt water, because the levels of humic-like fluorophores in river and sea-ice melt water are very different (Gonçalves-Araujo et al. 2016; Tanaka et al. 2016). The abovementioned studies imply that freshwater end-members can be specified and traced using humic-like fluorophores in combination with salinity, oxygen isotopes of water, or alkalinity in particular environments in coastal regions, such as a region where several freshwater sources with different levels of humic-like fluorophores make contributions to the coastal waters and where the photobleaching effect is low. However, at present, humic-like fluorophores have scarcely been applied to identify freshwater end-members in coastal environments.
The coastal region of southeastern Hokkaido, the northern island of Japan, is affected by the Oyashio Current. The Oyashio Current flows southwestward along the slope as a western boundary current of the subarctic gyre (Qiu 2001). Two typical water masses are seasonally present on the shelf of southeastern Hokkaido. The Modified Soya Warm Current Water (SWCW) derives from the Sea of Japan via the Sea of Okhotsk and strengthens from summer to autumn (Kono 1997; Isoda et al. 2003; Oguma et al. 2008). From winter to spring, the Coastal Oyashio Water (COW), defined as a water mass with a temperature lower than 2 °C and a salinity lower than 33.0 (Ohtani 1971; Hanawa and Mitsudera 1986), is widely distributed (Isoda et al. 2003; Kono et al. 2004; Oguma et al. 2008). COW can also be characterized as rich in dissolved iron in addition to macronutrients (Nakayama et al. 2010; Nishioka et al. 2011), and it possibly induces spring phytoplankton blooms in the Oyashio region (Kono and Sato 2010; Nakayama et al. 2010), where bloom-forming, microplankton-sized diatoms can be stressed by iron availability (Hattori-Saito et al. 2010). It has also been reported that spring diatom blooms in the region usually end by June or July due to the limited iron availability (Saito et al. 2002).
Three distinct sources have been proposed as freshwater end-members of COW. Ohtani (1971, 1989) pointed out that sea-ice melt water is an important freshwater end-member of COW. Other researchers (Isoda et al. 2003; Oguma et al. 2008; Kusaka et al. 2009) indicated a contribution of Eastern Sakhalin Current Water, which is affected by the Amur River (Mizuta et al. 2003), to COW. A contribution from local rivers in eastern Hokkaido to COW was also suggested (Oguma et al. 2007, 2008). However, spatiotemporal variability in the distribution of these freshwater end-members of COW has not been well documented.
In the study reported in the present paper, the spatial distributions of humic-like fluorophores were observed in the coastal region off southeastern Hokkaido in March 2015. The goal of this study was to determine the major freshwater end-members of COW during the observations. Water from various rivers in Hokkaido, estuarine water from the Amur River, and sea ice from the Sea of Okhotsk were used as freshwater end-members. Negative correlations between salinity and humic-like fluorophores are usually observed in coastal environments, as mentioned above, indicating that the levels of humic-like fluorophores in riverine end-members are higher than those in marine end-members in coastal environments. It is well established that levels of humic-like fluorophores in sea-ice melt water are low compared to seawater due to drainage with brine rejection during sea-ice formation (Stedmon et al. 2007, 2011; Müller et al. 2013). Therefore, to evaluate the major freshwater end-members of COW, it is important to assess the relationship between salinity and humic-like fluorophores.
2 Materials and methods
2.1 Observations and sample collection in COW and the Oyashio region
Observations of the Oyashio region, covering the COW, were carried out in March 2015 during a cruise on the R/V Hakuho Maru KH-15-1 (Fig. 1). An observation transect was followed along the “A-line” from off Akkeshi to southeast Hokkaido, Japan. Station A1 was observed 7 times from the 9th to the 20th (JST) during the cruise. The sampling dates for the other stations were as follows: 8th (station A0), 9th (station A2), 14th (station A3), 15th (station A4), 16th (stations A11 and A8), 17th (station A6), and 18th (station A5). In addition to the A-line, observations were carried out at eight stations in the region.
Seawater samples were generally collected from the surface to the bottom or 250 m using a conductivity-temperature-depth (CTD)-carousel multiple sampling (CMS) system (SBE-911plus and SBE-32 water samplers, Sea Bird Electronics, Inc.) equipped with acid-cleaned Niskin-X bottles. Samples were collected from the surface to ~ 5000 m at some stations. An acid-cleaned 0.22 μm Durapore filter (Millipak, Millipore) was attached directly to the spigot of the Niskin bottles, and seawater was gravity filtered into a precombusted glass vial with an acid-cleaned Teflon-lined cap after triple rinsing. The samples were then stored frozen in the dark until analysis (4–16 months). The temperature and salinity used in this study were collected by the CTD sensors. Chlorophyll a concentrations were determined with the fluorometric method of Welschmeyer (1994).
The current velocity data at station A1 were obtained by a vessel-mounted acoustic Doppler current profiler (ADCP) at 10-min intervals (Teledyne RD Instruments, broadband 76.8 kHz). After correcting the misalignment of the ADCP (Joyce 1989) and removing erroneous data whose percent good derived from the ADCP data was less than 80 as well as those obtained when the ship was accelerating, we obtained a velocity profile of each cast by temporally averaging the data during the cast.
2.2 Collection of sea-ice samples
Four sea-ice blocks were collected with a basket suspended from the ship’s crane over the ice surface in the southern Sea of Okhotsk (Fig. 1) during cruises aboard the icebreaker P/V Soya in February 2012, February 2013, and February 2014, according to Kanna et al. (2014). The sea-ice blocks were placed in double plastic bags and then stored frozen in the dark. In the onshore laboratory, a sea-ice block was broken into small pieces with an icepick and a ceramic knife, and small pieces were placed into an acid-cleaned Teflon beaker and melted in the dark at room temperature. Immediately after melting, the sea-ice melt water was filtered through a 0.22 μm filter (Durapore, Millipore) under a gentle vacuum, collected in precombusted glass vials with acid-cleaned, Teflon-lined caps after triple rinsing, and then stored at − 20 °C for 2 days until analysis. The salinity of the sea-ice samples was measured by an automatic salt/chloride analyzer (model SAT-210, Towa Electronic Industry) with a conversion factor for salinity, according to Kanna et al. (2014).
2.3 Collection of a sample in the estuary of the Amur River
One estuarine sample was collected at a station in the vicinity of the mouth of the Amur River (53.45°E, 142.00°N) on 8 September 2006 by the R/V Professor Khromov (Far Eastern Hydrometeorological Research Institute: FERHRI). The sampling procedure is described here only briefly, but is described in detail elsewhere (Nishioka et al. 2014). Surface water (2 m) was collected by the CTD-CMS system equipped with acid-cleaned Niskin-X bottles, filtered through a 0.22 μm Durapore filter (Millipak, Millipore), collected in an acid-cleaned FLPE bottle, and then stored frozen in the dark until analysis. The temperature and salinity used in this study were collected by the CTD sensors.
2.4 Collection of river water samples in Hokkaido, Japan
Observations of 33 rivers located in the southern and eastern parts of Hokkaido, Japan, were carried out on 18–20 September 2011. The hydrographs of the rivers during sampling could be characterized as base flow. The rivers consisted of small streams to the middle and lower reaches of relatively large rivers, such as the Tokachi, Kushiro, and Abashiri rivers. The upper reaches of the relatively large rivers are generally covered with forests (Woli et al. 2008; Muneoka et al. 2012). The middle reaches of the Tokachi and Abashiri rivers are covered with agricultural areas (Woli et al. 2008; Muneoka et al. 2012). The lower reaches of the Kushiro River flow through the Kushiro Mire (Ahn et al. 2008). Thus, the rivers observed in this study cover various types of watersheds: forests, agricultural areas, and wetlands. It is well established that the quantity and quality of DOM in river water are dependent on the watershed environment (e.g., Stedmon et al. 2003; Williams et al. 2010). As such, it can be expected that the riverine DOM observed in this study will show wide variability in quantity and quality due to the range of watershed environments.
River water samples were collected from the center of a bridge using a bucket that had been rinsed three times. The water sample was immediately filtered through a 0.45 μm filter (Durapore, Millipore) with an acid-cleaned plastic syringe, collected into an acid-cleaned polypropylene bottle, and then stored in a cooler and a refrigerator until analysis. Chemical analyses were carried out within 5 days after sample collection.
Daily discharge data for the local rivers in Hokkaido were obtained through the Water Information System provided by the Ministry of Land, Infrastructure, Transport and Tourism (http://www1.river.go.jp/).
2.5 Excitation–emission matrix fluorescence and parallel factor analysis
Excitation–emission matrix (EEM) fluorescence was determined using a fluorometer (FluoroMax-4, Horiba) according to Tanaka et al. (2014). The frozen samples of seawater, sea-ice melt water, and estuarine water were thawed and allowed to stand until they reached close to room temperature before the EEM measurements. The cooled river water samples were also allowed to stand until they reached near to room temperature before the EEM measurements. Emission scans from 290 to 550 nm taken at 2-nm intervals were acquired in the S/R mode for excitation wavelengths between 250 and 450 nm at 5-nm intervals. The bandpass was set to 5 nm for both excitation and emission. The fluorescence spectra were scanned with a 0.1-s integration time for river water and a 0.25-s integration time for seawater, sea-ice melt water, and estuarine water.
To correct the EEM data, inner-filter correction was carried out using the absorbance spectra (McKnight et al. 2001) determined on a spectrophotometer (UV-1800, Shimadzu) according to Yamashita et al. (2013). Quartz-windowed cells with path lengths of 1 and 5 cm were used for the absorbance analysis of river water and other samples (seawater, sea-ice melt water, and estuarine water), respectively. The EEM signal of Milli-Q water was subtracted from the sample EEM signals to eliminate the Raman scatter band. The specific instrument components were also corrected with the excitation and emission correction files supplied by the manufacturers. The fluorescence intensities in the EEMs were converted to Raman units (RU) using the area of the water Raman scatter peak at 350 nm excitation, which was analyzed daily (Lawaetz and Stedmon 2009).
Parallel factor analysis (PARAFAC) statistically decomposes EEMs into several fluorescent components and residues. PARAFAC modeling of EEMs has already been described in detail elsewhere (Stedmon et al. 2003; Stedmon and Bro 2008). PARAFAC analysis was conducted using MATLAB (MathWorks, Natick, MA, USA) with the DOMFluor toolbox (Stedmon and Bro 2008). The wavelength range used for PARAFAC was 250–455 and 290–520 nm for excitation and emission, respectively. Two river water samples were identified as outliers through the PARAFAC procedure, and the three-component model was validated by split-half validation and random initialization (Stedmon and Bro 2008).
3 Results
3.1 Hydrographic conditions during the observations
The spatial distributions of the temperature, salinity, and chlorophyll a concentration in the upper 250 m layer of the A-line are shown in Fig. 2. The lowest temperature (− 0.2 °C) and salinity (32.2) were observed at station A0, and the temperatures at depths shallower than 75 m gradually increased towards the offshore. COW, namely, the water mass characterized by a temperature lower than 2 °C and a salinity lower than 33.0, was observed at the surface layer at stations A0 to A6 along the transect. The temperature and salinity at depths deeper than 75 m at onshore stations were generally low compared with those at offshore stations, while a water mass characterized by relatively high temperature and salinity was distributed between 75 and 200 m at station A3.
Figure 3 shows the temporal changes in the current velocity at 27 m, the temperature, and the salinity during consecutive observations at station A1. A water mass characterized by low temperature (< 0 °C) and relatively high salinity (approximately 32.5) was distributed throughout the water column on 9 March. From 14 to 18 March, a water mass featuring a slightly higher temperature (~ 1 °C) and a lower salinity (< 32.4) was distributed in the surface layer. A water mass other than the COW was distributed in the water column deeper than 16 m on 14 March. The temperature and salinity were relatively uniform throughout the water column from 19 to 20 March (0.8–1.2 and 32.7–32.9 °C, respectively). The current direction did not change much during consecutive observations and was generally comparable to the climatological mean seasonal flow for the coastal region of south Hokkaido (Rosa et al. 2007). However, a low-pressure system developed during the cruise and passed over Hokkaido from south to north from 10 to 11 March 2015; thus, the low-pressure system may have led to significant changes in temperature and salinity at station A01 between 9 and 14 March.
The discharge from local rivers in eastern Hokkaido during winter (January–February) 2015 seemed typical, while the discharge during the first half of March 2015 appeared to be relatively high compared with that in other years. For example, at an observational station along the lower reaches of the Tokachi River (Moiwa), the average discharge in February 2015 (100 ± 3 m3 s−1) was comparable to the range observed in the 10 years preceding 2015 (104 ± 10 m3 s−1 in 2005, 101 ± 17 m3 s−1 in 2006, 109 ± 13 m3 s−1 in 2007, 95 ± 6 m3 s−1 in 2008, 80 ± 7 m3 s−1 in 2009, 104 ± 12 m3 s−1 in 2010, 124 ± 13 m3 s−1 in 2011, 114 ± 10 m3 s−1 in 2012, 137 ± 22 m3 s−1 in 2013, and 124 ± 11 m3 s−1 in 2014). However, the average discharge from 1 to 15 March 2015 (143 ± 54 m3 s−1) at the Moiwa station was higher than that during the same period in 2005–2014 (from 93 ± 7 m3 s−1 in 2005 to 119 ± 5 m3 s−1 in 2013).
Figure 4 shows a temperature–salinity (T–S) diagram for the seawater samples collected from the upper 250 m at all stations. Approximately 60% of the samples collected were characterized as COW. According to Nakayama et al. (2010), samples corresponding to a relatively high temperature and salinity could be characterized as modified Kuroshio Water (MKW), which detaches from the Kuroshio Extension (Yasuda et al. 1992). Other samples could be categorized as Oyashio Water (OYW).
The chlorophyll a concentration ranged from 0.01 to 4.01 mg m−3 in this study. Levels of chlorophyll a along the A-line were generally high in the surface layer and decreased with depth (Fig. 2). Higher levels (1.0–1.5 mg m−3) of chlorophyll a along the A-line were observed at onshore stations (i.e., A0 and A1), and the highest levels seen in this study (3.4–4.0 mg m−3) were observed at station I located at 145.29°E, 42.93°N. The chlorophyll a concentration observed in this study generally corresponded to prebloom periods because a long-term observation carried out from 1990 to 1998 found that the chlorophyll a concentration in the spring bloom of the Oyashio region ranged from 2.2 to 12.8 mg m−3, with a mean ± 1 standard error of 5.67 ± 3.6 mg m−3 (Saito et al. 2002).
3.2 EEM-PARAFAC
A three-component model was validated based on the PARAFAC modeling of four EEMs of sea-ice melt water, 31 EEMs of river water in Hokkaido, one EEM of estuary water from the Amur River, and 290 EEMs of seawater (Fig. 5), implying that the EEM of the dataset exhibited relatively small variations. Component 1 (C1) produced peaks at an emission wavelength of 480 nm from excitation wavelengths of < 250 and 350 nm. This component could be categorized as a humic-like fluorophore that is traditionally defined as terrestrial (Coble 1996). Component 2 (C2) could also be designated a humic-like fluorophore that is traditionally defined as marine because this component produced peaks at an emission wavelength of 398 nm from excitation wavelengths of < 250 and 315 nm (Coble 1996). In contrast, a peak produced at an emission wavelength of 334 nm from an excitation wavelength of 280 nm by component 3 (C3) represented a protein-like fluorophore, in particular a tryptophan molecule (Coble 1996; Yamashita and Tanoue 2003).
3.3 PARAFAC components in COW and the Oyashio region
The spatial distributions of the fluorescence intensities of individual PARAFAC components along the A-line are shown in Fig. 6. The distribution pattern of humic-like C1 is similar to that of humic-like C2. High levels of these humic-like components were generally found in the upper layer at onshore stations (A0 and A1) and in the water column deeper than 200 m. Low levels of humic-like components were evident in the water column shallower than 100 m at offshore stations (A6, A8, and A11) and at 75–200 m at station A3. Low levels of humic-like components corresponded to water masses characterized by high temperatures (Figs. 2, 6).
The spatial distribution of protein-like C3 was somewhat different from those of humic-like C1 and C2 (Fig. 6). The levels of protein-like C3 were generally high in the surface layers and decreased with depth, irrespective of the differences in the stations. In the surface layers, particularly high levels were evident at the onshore stations (A0 and A1). This distribution pattern of the protein-like component was similar to that of the chlorophyll a concentration (Figs. 2, 6).
Scatter plots between each PARAFAC component and salinity as well as the chlorophyll a concentration, with temperature on the z-axis, were determined for the COW observed in this study (Fig. 7). Negative linear relationships were evident between three PARAFAC components and salinity: [C1] = − 0.0072 ± 0.0006 × [salinity] + 0.25 ± 0.02, R2 = 0.49, n = 144, p < 0.001; [C2] = − 0.0091 ± 0.0009 × [salinity] + 0.31 ± 0.03, R2 = 0.42, n = 144, p < 0.001; and [C3] = − 0.0064 ± 0.0006 × [salinity] + 0.22 ± 0.02, R2 = 0.45, n = 144, p < 0.001.
The chlorophyll a concentrations were exceptionally high (3.4–4.0 mg m−3) for four samples obtained from 0–20 m at station I (Figs. 1, 7). Except for these samples, the correlation of the chlorophyll a concentration with protein-like C3 (r = 0.58, n = 140, p < 0.001) was better than those with humic-like C1 (r = 0.29, n = 140, p < 0.001) and C2 (r = 0.21, n = 140, p < 0.001).
3.4 PARAFAC components in possible freshwater end-members of COW
The fluorescence intensity of humic-like C1 ranged from 0.038 to 0.471 for river water, from 0.002 to 0.011 for sea-ice melt water, and was 0.457 for the Amur River estuarine water. The fluorescence intensity of humic-like C2 ranged from 0.037 to 0.500 for river water, from 0.003 to 0.012 for sea-ice melt water, and was 0.555 for the Amur River estuarine water. Among the river water sources, the highest levels of humic-like C1 and C2 were derived from the lower reaches of the Kushiro River, which flows through the Kushiro Mire. The fluorescence intensity of protein-like C3 ranged from 0.006 to 0.093 for river water, from 0.007 to 0.024 for sea-ice melt water, and was 0.124 for the Amur River estuarine water. Thus, if one compares these end-member levels with the levels found in COW (Fig. 7), the abundance of humic-like C1 and C2 was highest for river water samples (including the estuarine water sample), followed by COW, and then the sea-ice melt water samples. The levels of protein-like C3 were similar in some of the river water samples, sea-ice melt water samples, and COW, even though the estuarine water and other river water samples contained levels that were one order of magnitude higher than those in COW.
4 Discussion
COW was evident in the coastal region of southeastern Hokkaido during this study (Figs. 2, 3), which is typical for this region (Kusaka et al. 2009). Higher concentrations of dissolved iron were evident, corresponding to less-saline water during the A-line observations in January (Nishioka et al. 2011). Thus, the freshwater origin of COW is crucial to understanding the mechanism of iron supply and thus to clarifying the mechanisms of the induction and maintenance of spring phytoplankton blooms (in other words, the factors shaping the spatiotemporal distribution of spring phytoplankton blooms) in the Oyashio region. Two different freshwater sources, namely, river water and sea-ice melt water, have been considered the end-members of COW (Ohtani 1971, 1989; Oguma et al. 2007, 2008; Kusaka et al. 2009). Mizuta et al. (2003) indicated that the surface water of the East Sakhalin Current is characterized by less-saline East Sakhalin Current Water due to the contribution of Amur River water. It was also suggested that the local rivers of eastern Hokkaido supply freshwater to COW (Oguma et al. 2007, 2008).
Negative linear relationships between the humic-like and protein-like components derived from EEM-PARAFAC and salinity were observed for COW (Fig. 7), implying that the major factor controlling the abundance of these PARAFAC components in COW was the mixing of low (and/or moderate)-salinity water with high-salinity water. More importantly, the relationships imply that these components can be useful for evaluating the freshwater end-member(s) of COW. However, it has often been observed that the abundance of protein-like PARAFAC components, in particular tryptophan-like PARAFAC components, is highest in intermediate-salinity water in some coastal environments due to the contribution of autochthonous DOM (Yamashita et al. 2008; Fellman et al. 2010, 2011). In this study, the ranges of the abundance of the protein-like component were similar among some river water samples, sea-ice melt water samples, and COW, implying that the protein-like component is produced in terrestrial aquatic environments, in sea ice, and possibly in coastal environments.
It has recently been well documented that both the traditionally defined terrestrial and marine humic-like fluorophores are produced by marine microbes (e.g., Yamashita et al. 2010; Catalá et al. 2015; Goto et al. 2017; Zhao et al. 2017; Tada et al. 2017), implying that it is difficult to determine the origin of humic-like fluorophores from their spectral characteristics. However, the levels of humic-like fluorophores, including traditionally defined terrestrial and marine humic-like PARAFAC components, in river water are usually high enough to trace these species in coastal environments (e.g., Dorsch and Bidleman 1982; Hayase et al. 1987; Del Castillo et al. 1999; Yamashita et al. 2008). In addition, the levels of humic-like components in sea-ice melt water are generally low due to brine rejection during sea-ice formation (Stedmon et al. 2007, 2011; Müller et al. 2013). Such characteristics of humic-like components indicate that the freshwater end-member(s) of COW can be evaluated using the relationships between humic-like components and salinity.
Figure 8 shows the relationships between the humic-like components and salinity for river water, the Amur River estuarine water, and sea-ice melt water in addition to COW. A linear regression line between the individual humic-like components and salinity determined using the COW samples (Fig. 7a, c) was extrapolated to a salinity of 0 in Fig. 8a, b, respectively. The intercepts of the regressions against fluorescence intensity (0.25 ± 0.02 and 0.31 ± 0.03 for C1 and C2, respectively) were within the range of fluorescence intensities of humic-like C1 and C2 observed for the river water samples. The plots of the sea-ice melt water samples were very different from the regression lines for both humic-like C1 and C2. Furthermore, the levels of humic-like C1 and C2 in the sea-ice melt water samples were lower than those in COW. These results suggest minimal contributions from sea-ice melt water to COW at the time of sampling. The relatively low R2 values for the regression between humic-like components and salinity (Fig. 7) imply that the freshwater from various rivers possibly contributed to the COW observed in this study.
The plots of the Amur River estuarine water collected in September greatly deviated from the regression line between the humic-like components and salinity (Fig. 8a, b), but this relationship may not be directly comparable with that for COW because the concentration of riverine DOM, including humic-like components, generally increases with increasing river discharge (e.g., Spencer et al. 2009; Mann et al. 2012). The sampling of local rivers in Hokkaido was carried out during the base-flow period of September. Because the hydrographs of the local rivers in Hokkaido show base flow during winter (before the snowmelt), the levels of humic-like components in the local rivers of Hokkaido were possibly comparable between the base-flow periods of September and winter. It should be noted that a high-resolution western North Pacific general circulation model simulated an outflow of COW from the Sea of Okhotsk to the North Pacific through the Kunashiri Strait (and the Nemuro Strait) of approximately 0.5–1.2 Sv (= 106 m3 s−1) from January to April (Sakamoto et al. 2010). The discharge from the major rivers (i.e., the Tokachi, Kushiro, and Abashiri rivers) in eastern Hokkaido from January to March is on the order of 101–102 m3 s−1 for each river. These values suggest that the rivers connected to the Sea of Okhotsk are probably important as freshwater end-members of the COW observed in this study. Otherwise, the local rivers connected to the North Pacific may affect the COW only locally. Further studies are necessary to clarify the river(s) contributing to freshwater end-member(s) of COW.
It is interesting to note that two distinct water masses seemed to contribute less-saline water (< 32.5) to COW (Fig. 7a, c). The first water mass featured a lower temperature (< 0 °C) and relatively high levels of humic-like components. This water mass plotted near the regression line between humic-like components and salinity and seemed to mainly control the intercept with the humic-like components axis (Fig. 8). Temperatures below 0 °C and relatively high levels of humic-like components indicated that the river water was mixed with seawater and then cooled in a coastal environment to produce the features of this water mass. The other possible way to form the first water mass is through the influence of sea-ice melt water. A minor contribution from sea-ice melt water in addition to a major contribution from river water can produce moderate-salinity water. Subsequent mixing of moderate- and high-salinity water could form the first water mass. The second water mass was characterized by a relatively high temperature (> 0.8 °C; Fig. 7a, c). This water mass was observed in the surface layer at station A1 just after the passage of the low-pressure system (14–15 March; Fig. 3). The levels of humic-like components in this water mass were highest, and the plots of this water mass deviated slightly from the regression lines between humic-like components (in particular humic-like C1) and salinity. The deviations from the general regression lines imply that different rivers possibly contributed freshwater to the first and second water masses of the COW, respectively, and/or the sea-ice melt water contributions to the first and second water masses of the COW differed.
5 Conclusions and implications
This study is the first to apply the relationship between salinity and humic-like fluorescence to evaluate the distribution of two distinct freshwater end-members in a coastal environment. The novel approach used in this study clarified that river water is the major freshwater end-member of the COW observed in this study. However, the approach could not be used to evaluate the contribution from sea-ice melt water to COW. Because the major freshwater end-member(s) of COW possibly change spatially and temporally, a comprehensive evaluation of the temperature, salinity, and humic-like fluorescence from winter to spring over a wider area (including the Sea of Okhotsk) is necessary. Moreover, the addition of different parameters that can evaluate freshwater end-members, e.g., δ18O of water (Oguma et al. 2007, 2008), would enable better evaluation of the spatiotemporal variations in the contributions of river water and sea-ice melt water to COW. In addition, a thorough investigation of the humic-like fluorescence in local rivers in Hokkaido, the Amur River and other rivers in Sakhalin should be carried out to identify the major river(s) that serve as the freshwater end-members of COW.
Two humic-like PARAFAC components, i.e., terrestrial humic-like C1 and marine humic-like C2 according to the traditional definitions, seemed to be useful for evaluating the freshwater end-members of COW. Both humic-like components are also produced in the open ocean by marine microbes (e.g., Yamashita et al. 2010; Catalá et al. 2015). Different behaviors of humic-like components (i.e., conservative and nonconservative behavior for terrestrial and marine humic-like components, respectively) were also observed in coastal environments (Yamashita et al. 2008; Cawley et al. 2014). Thus, in future studies, it would be better to use terrestrial humic-like components rather than marine humic-like components to evaluate the freshwater end-members of COW. An in situ fluorescence sensor that has excitation and emission wavelengths close to the peak of the terrestrial humic-like component (e.g., Yamashita et al. 2015b) would also be applicable to such future COW studies.
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Acknowledgements
The authors thank the captain, crew, and scientists on board the R/V Hakuho Maru, P/V Soya, and R/V Professor Khromov for their help with the observations. We are grateful to O. Seki for the collection of some of the river water samples. We also thank three anonymous reviewers for their helpful/constructive comments and suggestions, which helped improve the quality of this manuscript. This research was partially supported by a Grant-in-Aid for Scientific Research (nos. 24121003, JP15H05820, JP15H05818, 16H02930, 17H00775), the Arctic Challenge for Sustainability (ArCS) Project, and the Grant for Joint Research Program of Institute of Low Temperature Science, Hokkaido University.
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Mizuno, Y., Nishioka, J., Tanaka, T. et al. Determination of the freshwater origin of Coastal Oyashio Water using humic-like fluorescence in dissolved organic matter. J Oceanogr 74, 509–521 (2018). https://doi.org/10.1007/s10872-018-0477-x
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DOI: https://doi.org/10.1007/s10872-018-0477-x