Your search keyword '"Mortensen, John"' showing total 5 results

1. Arctic benthos in the Anthropocene: Distribution and drivers of epifauna in West Greenland.

Author

Maier SR, Arboe NH, Christiansen H, Krawczyk DW, Meire L, Mortensen J, Planken K, Schulz K, van der Kaaden AS, Vonnahme TR, Zwerschke N, and Blicher M

Subjects

Greenland, Arctic Regions, Animals, Biomass, Environmental Monitoring, Aquatic Organisms, Ice Cover, Climate Change, Biodiversity, Ecosystem

Abstract

Albeit remote, Arctic benthic ecosystems are impacted by fisheries and climate change. Yet, anthropogenic impacts are poorly understood, as benthic ecosystems and their drivers have not been mapped over large areas. We disentangle spatial patterns and drivers of benthic epifauna (animals living on the seabed surface) in West Greenland, by integrating an extensive beam-trawl dataset (326 stations, 59-75°N, 30-1400 m water depth) with environmental data. We find high variability at different spatial scales: (1) Epifauna biomass decreases with increasing latitude, sea-ice cover and water depth, related to food limitation. (2) In Greenland, the Labrador Sea in the south shows higher epifauna taxon richness compared to Baffin Bay in the north. Τhe interjacent Davis Strait forms a permeable boundary for epifauna dispersal and a mixing zone for Arctic and Atlantic taxa, featuring regional biodiversity hotspots. (3) The Labrador Sea and Davis Strait provide suitable habitats for filter-feeding epifauna communities of high biomass e.g., sponges on the steep continental slope and sea cucumbers on shallow banks. In Baffin Bay, the deeper continental shelf, more gentle continental slope, lower current speed and lower phytoplankton biomass promote low-biomass epifauna communities, predominated by sea stars, anemones, or shrimp. (4) Bottom trawling reduces epifauna biomass and taxon richness throughout the study area, where sessile filter feeders are particularly vulnerable. Climate change with diminished sea ice cover in Baffin Bay may amplify food availability to epifauna, thereby increasing their biomass. While more species might expand northward due to the general permeability of Davis Strait, an extensive colonization of Baffin Bay by high-biomass filter-feeding epifauna remains unlikely, given the lack of suitable habitats. The pronounced vulnerability of diverse and biomass-rich epifauna communities to bottom trawling emphasizes the necessity for an informed and sustainable ecosystem-based management in the face of rapid climate change., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

2. Metazooplankton community structure, feeding rate estimates, and hydrography in a meltwater-influenced Greenlandic fjord

Author

Tang, Kam W., Nielsen, Torkel Gissel, Munk, Peter, Mortensen, John, Møller, Eva Friis, Arendt, Kristine Engel, Tönnesson, Kajsa, and Juul-Pedersen, Thomas

Published

2011

3. Subglacial Discharge and Its Down‐Fjord Transformation in West Greenland Fjords With an Ice Mélange.

Author

Mortensen, John, Rysgaard, Søren, Bendtsen, Jørgen, Lennert, Kunuk, Kanzow, Torsten, Lund, Henrik, and Meire, Lorenz

Subjects

FRESH water, MARINES, WATER masses, CHEMICAL properties, GLACIERS

Abstract

Buoyant freshwater released at depth from under Greenland's marine‐terminating glaciers gives rise to vigorous buoyant discharge plumes adjacent to the termini. The water mass found down fjord formed by mixing of buoyant subglacial freshwater and ambient fjord water and subsequent modification by glacial ice melt in the ice mélange is referred to as subglacial water. It substantially affects both the physical and chemical properties of the fjords' marine environment. Despite the importance of this freshwater source, many uncertainties remain regarding its transformation and detection. Here we present observations close to a marine‐terminating glacier in a fjord with substantial ice mélange and follow the down‐fjord changes of the subglacial discharge plume. Heat brought to the surface by entrainment of warm ambient fjord water into the rising plume causes intense melting of the ice mélange close to the plume pool. This results in an increase of glacial ice melt fraction to total glacial meltwater from 1–2% in the plume pool to ~18% eleven kilometers down‐fjord, with the largest increase being observed within the first few kilometers. Down‐fjord of the ice mélange two temperature minima bound the layer containing subglacial water. The upper bound is linked to the adjacent ice mélange and down‐fjord runoff sources, whereas the lower bound is linked to the stratification of the ambient water. We show that similar bounds can be observed in other marine‐terminating glacier fjords along West Greenland that contain an ice mélange, suggesting that similar processes work in other fjords. Key Points: We present hydrographic observations from a subglacial discharge plume pool and ice mélange adjacent to a Greenland tidewater glacierThe glacial ice melt fraction in the plume pool is estimated at 1–2% of the total freshwater fraction, increasing to 12% within 2 kmThe interpretation of glacier‐derived meltwater stratification depends highly on the types of freshwater sources [ABSTRACT FROM AUTHOR]

Published

2020

4. Marine-terminating glaciers sustain high productivity in Greenland fjords.

Author

Meire, Lorenz, Mortensen, John, Meire, Patrick, Juul‐Pedersen, Thomas, Sejr, Mikael K., Rysgaard, Søren, Nygaard, Rasmus, Huybrechts, Philippe, and Meysman, Filip J. R.

Subjects

*GREENLAND ice, *GLACIERS, *TERRITORIAL waters, *CRYOSPHERE, *OCEANOGRAPHY

Abstract

Accelerated mass loss from the Greenland ice sheet leads to glacier retreat and an increasing input of glacial meltwater to the fjords and coastal waters around Greenland. These high latitude ecosystems are highly productive and sustain important fisheries, yet it remains uncertain how they will respond to future changes in the Arctic cryosphere. Here we show that marine-terminating glaciers play a crucial role in sustaining high productivity of the fjord ecosystems. Hydrographic and biogeochemical data from two fjord systems adjacent to the Greenland ice sheet, suggest that marine ecosystem productivity is very differently regulated in fjords influenced by either land-terminating or marine-terminating glaciers. Rising subsurface meltwater plumes originating from marine-terminating glaciers entrain large volumes of ambient deep water to the surface. The resulting upwelling of nutrient-rich deep water sustains a high phytoplankton productivity throughout summer in the fjord with marine-terminating glaciers. In contrast, the fjord with only land-terminating glaciers lack this upwelling mechanism, and is characterized by lower productivity. Data on commercial halibut landings support that coastal regions influenced by large marine-terminating glaciers have substantially higher marine productivity. These results suggest that a switch from marine-terminating to land-terminating glaciers can substantially alter the productivity in the coastal zone around Greenland with potentially large ecological and socio-economic implications. [ABSTRACT FROM AUTHOR]

Published

2017

5. Freshwater Fluxes East of Greenland.

Author

Dickson, Robert R., Rhines, Peter, Holfort, Jürgen, Hansen, Edmond, Østerhus, Svein, Dye, Stephen, Jónsson, Steingrímur, Meincke, Jens, Mortensen, John, and Meredith, Michael

Abstract

The northern North Atlantic features areas of strong surface cooling which sets up a southward flow of sinking cold, dense waters in the deep ocean. A northward flow of warm surface waters replaces the sinking southbound waters; a loop often termed the meridional overturning circulation (MOC). The associated northward heat transport is an important moderator of the high latitude climate along the flow. It is a major concern that excessive amounts of freshwater added to the northern North Atlantic could alter the dense water formation and associated ocean density contrasts driving this part of the MOC (Häkkinen 1999; Haak et al. 2003). The region has been undergoing a remarkable freshening since the mid-1960s (Curry and Mauritzen 2005; Curry et al. 2003; Dickson et al. 2002). Sources of freshwater input are runoff from Greenland, net precipitation, and export of freshwater from the Arctic in the form of sea ice and melt water through Fram Strait and the Canadian Archipelago. In the late 1960s a major freshening event contributed with as much as half of the extra freshwater required to account for the observed 1965-1995 freshening (Curry and Mauritzen 2005). The event was labeled the Great Salinity Anomaly (GSA) (Dickson et al. 1988), and appeared as extraordinarily fresh water circulating in the Subpolar gyre during the 1970s. The freshwater release has been attributed to an anomalous export of sea ice through Fram Strait during the late 1960s (Häkkinen 1993; Karcher et al. 2005). Pulses of excess freshwater and sea ice appear to have been emitted from the Arctic also after the GSA; both the 1980s and 1990s featured appearances of low salinity water in the Subpolar gyre (Belkin 2004). Karcher et al. (2005) attributed the salinity anomaly of the 1990s to a large release of liquid freshwater from the Arctic through Fram Strait. [ABSTRACT FROM AUTHOR]

Published

2008