e. coefficient bbp(443) normalised to Chl a values), it takes the value of 0.0030(± 0.0019) m2 mg− 1. When we compare the latter with the literature value of the average chlorophyll-specific backscattering coefficient at the relatively close wavelength of 470 nm given by McKee & Cunningham (2006) for Irish Sea waters (i.e. with the value of b*(Chl a)bp (443) = 0.0050(± 0.0009) m2 mg− 1), the differences are obvious. Such a comparison may suggest that the average efficiency of light
Selleck MDX-010 backscattering (in the blue part of the spectrum) per unit concentration of chlorophyll a for Baltic Sea suspended matter is about 40% less than for Irish Sea waters. The only statistical formula from Table 1 that can be compared with literature results in a straightforward way is the formula for estimating POC as a function of bbp(555). This formula, which has only a slightly less attractive standard error factor (X = 1.65) than the formula (3) suggested earlier, takes the following form (see Figure 4): equation(5) POC=14.9(bbp(555))0.769.POC=14.9bbp5550.769. It can be directly compared with the two linear relationships given by Stramski et al. (2008) for the
eastern South Pacific and the eastern Atlantic Oceans (one variant representing all the data of Stramski et al. is POC = 70.851bbp(555) − 0.009088, while another AZD6244 variant for which these authors excluded Chilean upwelling data is POC = 53.607bbp (555) + 0.002468) and also with the linear relationship given by Loisel et al. (2001) for the Mediterranean Sea (POC = 37.75 bbp (555) + 0.0013) (see the additional dotted
and dashed lines in Figure 4). As can be seen for low values of bbp(555), of about 0.005 m− 1, Mannose-binding protein-associated serine protease both oceanic formulas according to Stramski et al. (2008) would produce estimated average results in relative agreement with those given by formula (5), but for bbp(555) values larger by about one order of magnitude (i.e. values of about 0.05 m− 1) there would be a distinct overestimation of POC concentration when compared to the results obtained with the Baltic Sea formula. The linear formula according to Loisel et al. (2001) obtained for the Mediterranean Sea generally stands in better agreement with formula (5) for the range of bbp(555) values registered in the Baltic Sea, but obviously there are also differences for the low and high values of bbp(555) as a result of the nonlinearity of formula (5). The above presentation of IOP-based relationships for the two satellite light wavelengths of 443 and 555 nm can be supplemented with examples of similar relationships but determined at the optimal bands chosen directly from among the available empirical material.