Spatiotemporal variability of micronekton at two central North Pacific Fronts

The North Pacific Subtropical Frontal Zone (STFZ) seasonally aggregates economically important fish and protected species. The aggregation of top predators is hypothesized to be a response to convergent flow at the prominent thermohaline Subtropical Front (STF) in the STFZ and a sharp northward incr...

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Bibliographic Details
Published in:Deep-sea research. Part I, Oceanographic research papers Oceanographic research papers, 2023-08, Vol.198, p.104076, Article 104076
Main Author: Domokos, Réka
Format: Article
Language:English
Subjects:
Acoustic scattering layers
Environmental forcing
Micronekton
North Pacific subtropical frontal zone (STFZ)
Subtropical front (STF)
Transition zone chlorophyll front (TZCF)
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Summary:The North Pacific Subtropical Frontal Zone (STFZ) seasonally aggregates economically important fish and protected species. The aggregation of top predators is hypothesized to be a response to convergent flow at the prominent thermohaline Subtropical Front (STF) in the STFZ and a sharp northward increase in primary productivity, the Transition Zone Chlorophyll Front (TZCF), which is thought to link primary productivity to top predators via secondary and tertiary consumers. Given existing data gaps in our knowledge on forage biomass, distribution, and composition in the area, characteristics of micronekton, forage for top predators, were investigated using in situ multi-frequency active acoustics from three springtime shipboard surveys conducted along the 158°W meridional. The effects of STF and TZCF on micronekton was accessed using in situ CTD profiles. Results of this study showed a significant positive effect of the STF on micronekton biomass. The acoustic data implied that the STF also acted as a boundary for the distribution of micronekton with differing taxonomic composition from south to its north. The TZCF, as well as Chl-a concentrations, did not show a significant effect on micronekton relative biomass or composition that might be due to effects of larger-scale variability masked in the in situ data. Contrary to expectation, significantly higher relative micronekton biomass was associated with higher temperatures, the mechanisms of which still need to be determined. •Acoustic data from this study reveal increased micronekton biomass and change in composition at the Subtropical Front.•The Transition Zone Chlorophyll Front did not have a significant effect on micronekton composition or biomass.•Higher temperatures were associated with an increase in micronekton biomass.•A marked increase in biomass with changed composition during the 2015 Survey could be a response to an extreme warming event.
ISSN:0967-0637
1879-0119
DOI:10.1016/j.dsr.2023.104076