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Introduction Ocean fronts are moving ephemeral biological hotspots forming at the interface of cooler and warmer waters. In the open ocean, this is where marine organisms, ranging from plankton to mesopelagic fish up to megafauna, gather and where most fishing activities concentrate. Fronts are critical ecosystems so that understanding their spatio-temporal variability is essential not only for conservation goals but also to ensure sustainable fisheries. The Mozambique Channel (MC) is an ideal laboratory to study ocean front variability due to its energetic flow at sub-to-mesoscales, its high biodiversity and the currently debated conservation initiatives. Meanwhile, fronts detection relying solely on remotely-sensed Sea Surface Temperature (SST) cannot access aspects of the subsurface frontal activity that may be relevant for understanding ecosystem dynamics. Method In this study, we used the Belkin and O’Reilly Algorithm on remotely-sensed SST and hindcasts of a high-resolution nested ocean model to investigate the spatial and seasonal variability of temperature fronts at different depths in the MC. Results We find that the seasonally varying spatial patterns of frontal activity can be interpreted as resulting from main features of the mean circulation in the MC region. In particular, horizontally, temperature fronts are intense and frequent along continental shelves, in islands’ wakes, at the edge of eddies, and in the pathways of both North-East Madagascar Current (NEMC) and South-East Madagascar Current (SEMC). In austral summer, thermal fronts in the MC are mainly associated with the Angoche upwelling and seasonal variability of the Mozambique current. In austral winter, thermal fronts in the MC are more intense when the NEMC and the Seychelles-Chagos and South Madagascar upwelling cells intensify. Vertically, the intensity of temperature fronts peaks in the vicinity of the mean thermocline. Discussion Considering the marked seasonality of frontal activity evidenced here and the dynamical connections of the MC circulation with equatorial variability, our study calls for addressing longer timescales of variability to investigate how ocean ecosystem/front interactions will evolve with climate change.
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Response of biological productivity to North Atlantic marine front migration during the Holocene
Abstract. Marine fronts delineate the boundary between distinct water masses and,through the advection of nutrients, are important facilitators of regionalproductivity and biodiversity. As the modern climate continues to change, themigration of frontal zones is evident, but a lack of information about theirstatus prior to instrumental records hinders future projections. Here, wecombine data from lipid biomarkers (archaeal isoprenoid glycerol dibiphytanylglycerol tetraethers and algal highly branched isoprenoids) with planktic andbenthic foraminifera assemblages to detail the biological response of themarine Arctic and polar front migrations on the North Iceland Shelf (NIS) overthe last 8 kyr. This multi-proxy approach enables us to quantify thethermal structure relating to Arctic and polar front migration and test howthis influences the corresponding changes in local pelagic productivity. Ourdata show that following an interval of Atlantic water influence, the Arcticfront and its associated high pelagic productivity migrated southeastward tothe NIS by ∼6.1 ka. Following a subsequent trend in regionalcooling, Polar Water from the East Greenland Current and the associated polarfront spread onto the NIS by ∼3.8 ka, greatly diminishinglocal algal productivity through the Little Ice Age. Within the last century,the Arctic and polar fronts have moved northward back to their currentpositions relative to the NIS and helped stimulate the productivity thatpartially supports Iceland's economy. Our Holocene records from the NISprovide analogues for how the current frontal configuration and theproductivity that it supports may change as global temperatures continue torise.
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- Award ID(s):
- 1804504
- PAR ID:
- 10439744
- Date Published:
- Journal Name:
- Climate of the Past
- Volume:
- 17
- Issue:
- 1
- ISSN:
- 1814-9332
- Page Range / eLocation ID:
- 379 to 396
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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- Free Publicly Accessible Full Text
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Accepted Manuscript1.0
- Journal Article:
- https://doi.org/10.5194/cp-17-379-2021
