Abstract
The Nordic Seas and the Fram Strait regions are a melting pot of a number of water masses characterized by distinct optical water properties. The warm Atlantic Waters transported from the south and the Arctic Waters from the north, combined with the melt waters contributing to the Polar Waters, mediate the dynamic changes of the year-to-year large-scale circulation patterns in the area, which often form complex frontal zones. In the last decade, moreover, a significant shift in phytoplankton phenology in the area has been observed, with a certain northward expansion of temperate phytoplankton communities into the Arctic Ocean which could lead to a deterioration in the performance of remote sensing algorithms. In this research, we exploited the capability of the satellite sensors to monitor those inter-annual changes at basin scales. We propose locally adjusted algorithms for retrieving chlorophyll a concentrations Chla, absorption by particles ap at 443 and 670 nm, and total absorption atot at 443 and 670 nm developed on the basis of intensive field work conducted in 2013–2015. Measured in situ hyper spectral remote sensing reflectance has been used to reconstruct the MODIS and OLCI spectral channels for which the proposed algorithms have been adapted. We obtained MNB ≤ 0.5% for ap(670) and ≤3% for atot(670) and Chla. RMS was ≤30% for most of the retrieved optical water properties except ap(443) and Chla. The mean monthly mosaics of ap(443) computed on the basis of the proposed algorithm were used for reconstructing the spatial and temporal changes of the phytoplankton biomass in 2013–2015. The results corresponded very well with in situ measurements.
Highlights
Climate change processes are the most pronounced in the Arctic, where the rate of temperature rise is the strongest [1]
In the blue part of the spectrum, there is a superposition of several processes such as the CDOM absorption increasing towards the shortwave, scattering of suspended particles and absorption by phytoplankton pigments with a maximum at 443 nm
The Rrs(670) maximum could be used as a diagnostic tool to distinguish between remote sensing reflectance spectra that were most likely shaped by factors other than absorption and scattering due to autotrophic protist growth
Summary
Climate change processes are the most pronounced in the Arctic, where the rate of temperature rise is the strongest [1]. Increasing temperatures lead to the reduction and thinning of the sea ice cover [2,3,4]. During last 10 years, the sea ice extents were the lowest on record [5]. The reduction in sea ice cover area and sea ice thickness is exposing more open water areas to the absorption of light [6] and the dissipation of this absorbed energy into heat. This positive feedback (ice-albedo feedback) may influence upper ocean layer thermodynamics and accelerate warming [7]. The amount of energy absorbed by oceanic water depends solely on its inherent optical properties (IOPs): these are additive functions of the spectral IOPs of clear water alone and the spectral
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