Exploring the Potential Impact of Greenland Meltwater on Stratification, Photosynthetically Active Radiation, and Primary Production in the Labrador Sea

Oliver, H. R.; Luo, Hongde; Castelao, Renato M.; Dijken, Gert L. van; Mattingly, Kyle S.; Rosen, Joshua J.; Mote, Thomas L.; Arrigo, Kevin R.; Rennermalm, Å. K.; Tedesco, Marco; Yager, Patricia L.

doi:10.1002/2018jc013802

Cited by 40 publications

(41 citation statements)

References 125 publications

(233 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The chemical composition of glacial discharge is now relatively well constrained, especially around Greenland (Yde et al, 2014;Meire et al, 2016a;Stevenson et al, 2017), Alaska (Hood and Berner, 2009;Schroth et al, 2011) and Svalbard (Hodson et al, 2004(Hodson et al, , 2016. Whilst high particle loads (Chu et al, 2012;Overeem et al, 2017) and Si are often associated with glacially modified waters ( Fig. 3a) around the Arctic (Brown et al, 2010;Meire et al, 2016a), the concentrations of all macronutrients in glacial discharge (Meire et al, 2016a) are relatively low and similar to those of coastal seawater (Fig.…”

Section: Effects Of Glacial Discharge On Marine Resource Availabilitymentioning

confidence: 99%

“…Quantifying the magnitude of environmental perturbations from glacial discharge is complicated by the multiple concurrent, and occasionally counteracting, effects that glacial discharge has in the marine environment. For example, ice-rock abrasion means that glacially fed rivers can carry higher sediment loads than temperate rivers (Chu et al, 2009;Overeem et al, 2017). Extensive sediment plumes where glacier discharge first enters the ocean limit light penetration into the water column (Murray et al, 2015;Halbach et al, 2019), and ingestion of glacial flour particles can be hazardous, or even fatal, to zooplankton, krill and benthic fauna (White and Dagg, 1989;Włodarska-Kowalczuk and Pearson, 2004;Arendt et al, 2011;Fuentes et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Review article: How does glacier discharge affect marine biogeochemistry and primary production in the Arctic?

et al. 2020

View full text Add to dashboard Cite

Abstract. Freshwater discharge from glaciers is increasing across the Arctic in response to anthropogenic climate change, which raises questions about the potential downstream effects in the marine environment. Whilst a combination of long-term monitoring programmes and intensive Arctic field campaigns have improved our knowledge of glacier–ocean interactions in recent years, especially with respect to fjord/ocean circulation, there are extensive knowledge gaps concerning how glaciers affect marine biogeochemistry and productivity. Following two cross-cutting disciplinary International Arctic Science Committee (IASC) workshops addressing the importance of glaciers for the marine ecosystem, here we review the state of the art concerning how freshwater discharge affects the marine environment with a specific focus on marine biogeochemistry and biological productivity. Using a series of Arctic case studies (Nuup Kangerlua/Godthåbsfjord, Kongsfjorden, Kangerluarsuup Sermia/Bowdoin Fjord, Young Sound and Sermilik Fjord), the interconnected effects of freshwater discharge on fjord–shelf exchange, nutrient availability, the carbonate system, the carbon cycle and the microbial food web are investigated. Key findings are that whether the effect of glacier discharge on marine primary production is positive or negative is highly dependent on a combination of factors. These include glacier type (marine- or land-terminating), fjord–glacier geometry and the limiting resource(s) for phytoplankton growth in a specific spatio-temporal region (light, macronutrients or micronutrients). Arctic glacier fjords therefore often exhibit distinct discharge–productivity relationships, and multiple case-studies must be considered in order to understand the net effects of glacier discharge on Arctic marine ecosystems.

show abstract

Section: Effects Of Glacial Discharge On Marine Resource Availabilitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Review article: How does glacier discharge affect marine biogeochemistry and primary production in the Arctic?

et al. 2020

View full text Add to dashboard Cite

show abstract

“…In addition to the carbon sink arising from high productivity in some fjords, the mixing of glacial melt with ambient ocean waters results in fjord waters that are significantly undersaturated in CO 2 , suggesting that glacially influenced coastal waters constitute important CO 2 sinks along the Greenland margins (Rysgaard et al, 2012;Fransson et al, 2015;Meire et al, 2015). The correlation between the distribution of meltwater and timing of phytoplankton blooms on parts of the Greenland continental shelf further suggests that meltwater arrival may also be a factor in summertime bloom initiation beyond the confines of glacierfjord systems (Arrigo et al, 2017;Oliver et al, 2018). However, large-scale impacts of freshwater export from the GrIS as a result of the potential export of glacially derived iron to iron-limited regions of the North Atlantic, remain poorly constrained owing to a limited understanding of the fate of glacially modified waters and their nutrients beyond the confines of Greenland's fjords.…”

Section: Impact On Ocean Biogeochemistry and Marine Ecosystemsmentioning

confidence: 99%

The Case for a Sustained Greenland Ice Sheet-Ocean Observing System (GrIOOS)

et al. 2019

View full text Add to dashboard Cite

Rapid mass loss from the Greenland Ice Sheet (GrIS) is affecting sea level and, through increased freshwater and sediment discharge, ocean circulation, sea-ice, biogeochemistry, and marine ecosystems around Greenland. Key to interpreting ongoing and projecting future ice loss, and its impact on the ocean, is understanding exchanges of heat, freshwater, and nutrients that occur at the GrIS marine margins. Processes governing these exchanges are not well understood because of limited observations from the regions where glaciers terminate into the ocean and the challenge of modeling the spatial and temporal scales involved. Thus, notwithstanding their importance, ice sheet/ocean exchanges are poorly represented or not accounted for in models used for projection studies. Widespread community consensus maintains that concurrent and long-term records of glaciological, oceanic, and atmospheric parameters at the ice sheet/ocean margins are key to addressing this knowledge gap by informing understanding, and constraining and validating models. Through a series of workshops and documents endorsed by the community-at-large, a framework for an international, collaborative, Greenland Ice sheet-Ocean Observing System (GrIOOS), that addresses the needs of society in relation to a changing GrIS, has been proposed. This system would consist of a set of ocean, glacier, and atmosphere essential variables to be collected at a number of diverse sites around Greenland for a minimum of two decades. Internationally agreed upon data protocols and data sharing policies would guarantee uniformity and availability of the information for the broader community. Its

show abstract

“…These regions could be a significant trap of dissolved inorganic phases (Meire, Mortensen, Meire, Juul-Pedersen, Sejr et al, 2017), and have the potential to prevent the nutrient-rich glacial waters reaching the coastal seas. Despite this possibility, distal summer phytoplankton blooms have been detected off Southwest Greenland in association with glacial melt (Arrigo, van Dijken, Castelao, Luo, Rennermalm et al, 2017) and ecosystem models indicate sensitivity to meltwater input (Oliver, Luo, Castelao, van Dijken, Mattingly et al, 2018). An understanding of how natural resourcesincluding fisheries, bird, and mammal stocks that are essential for food and encouraging tourism -will respond in the future to increasing anthropogenic stress on a regional and global scale relies on an understanding of foundational processes of these ecosystem services, including marine biogeochemistry and the sources and sinks of essential nutrients (Berthelsen, 2014;Meire et al, 2017;Weatherdon, Magnan, Rogers, Sumaila & Cheung, 2016).…”

Section: Introductionmentioning

confidence: 99%

The biogeochemical impact of glacial meltwater from Southwest Greenland

Hendry

Huvenne

Robinson

et al. 2019

Progress in Oceanography

View full text Add to dashboard Cite

Biogeochemical cycling in high-latitude regions has a disproportionate impact on global nutrient budgets. Here, we introduce a holistic, multidisciplinary framework for elucidating the influence of glacial meltwaters, shelf currents, and biological production on biogeochemical cycling in high-latitude continental margins, with a focus on the silica cycle. Our findings highlight the impact of significant glacial discharge on nutrient supply to shelf and slope waters, as well as surface and benthic production in these regions, over a range of timescales from days to thousands of years. Whilst biological uptake in fjords and strong diatom activity in coastal waters maintains low dissolved silicon concentrations in surface waters, we find important but spatially heterogeneous additions of particulates into the system, which are transported rapidly away from the shore. We expect the glacially-derived particles-together with biogenic silica tests-to be cycled rapidly through shallow sediments, resulting in a strong benthic flux of dissolved silicon. Entrainment of this benthic silicon into boundary currents may supply an important source of this key nutrient into the Labrador Sea, and is also likely to recirculate back into the deep fjords inshore. This study illustrates how geochemical and oceanographic analyses can be used together to probe further into modern nutrient cycling in this region, as well as the palaeoclimatological 3 approaches to investigating changes in glacial meltwater discharge through time, especially during periods of rapid climatic change in the Late Quaternary.

show abstract

Exploring the Potential Impact of Greenland Meltwater on Stratification, Photosynthetically Active Radiation, and Primary Production in the Labrador Sea

Cited by 40 publications

References 125 publications

Review article: How does glacier discharge affect marine biogeochemistry and primary production in the Arctic?

Review article: How does glacier discharge affect marine biogeochemistry and primary production in the Arctic?

The Case for a Sustained Greenland Ice Sheet-Ocean Observing System (GrIOOS)

The biogeochemical impact of glacial meltwater from Southwest Greenland

Contact Info

Product

Resources

About