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1. A warm jet in a cold ocean.

Author

MacKinnon, Jennifer A, Simmons, Harper L, Hargrove, John, Thomson, Jim, Peacock, Thomas, Alford, Matthew H, Barton, Benjamin I, Boury, Samuel, Brenner, Samuel D, Couto, Nicole, Danielson, Seth L, Fine, Elizabeth C, Graber, Hans C, Guthrie, John, Hopkins, Joanne E, Jayne, Steven R, Jeon, Chanhyung, Klenz, Thilo, Lee, Craig M, Lenn, Yueng-Djern, Lucas, Andrew J, Lund, Björn, Mahaffey, Claire, Norman, Louisa, Rainville, Luc, Smith, Madison M, Thomas, Leif N, Torres-Valdés, Sinhué, and Wood, Kevin R

Abstract

Unprecedented quantities of heat are entering the Pacific sector of the Arctic Ocean through Bering Strait, particularly during summer months. Though some heat is lost to the atmosphere during autumn cooling, a significant fraction of the incoming warm, salty water subducts (dives beneath) below a cooler fresher layer of near-surface water, subsequently extending hundreds of kilometers into the Beaufort Gyre. Upward turbulent mixing of these sub-surface pockets of heat is likely accelerating sea ice melt in the region. This Pacific-origin water brings both heat and unique biogeochemical properties, contributing to a changing Arctic ecosystem. However, our ability to understand or forecast the role of this incoming water mass has been hampered by lack of understanding of the physical processes controlling subduction and evolution of this this warm water. Crucially, the processes seen here occur at small horizontal scales not resolved by regional forecast models or climate simulations; new parameterizations must be developed that accurately represent the physics. Here we present novel high resolution observations showing the detailed process of subduction and initial evolution of warm Pacific-origin water in the southern Beaufort Gyre.

Published
2021

5. A warm jet in a cold ocean

Author

MacKinnon, Jennifer A, Simmons, Harper L, Hargrove, John, Thomson, Jim, Peacock, Thomas, Alford, Matthew H, Barton, Benjamin I, Boury, Samuel, Brenner, Samuel D, Couto, Nicole, Danielson, Seth L, Fine, Elizabeth C, Graber, Hans C, Guthrie, John, Hopkins, Joanne E, Jayne, Steven R, Jeon, Chanhyung, Klenz, Thilo, Lee, Craig M, Lenn, Yueng-Djern, Lucas, Andrew J, Lund, Björn, Mahaffey, Claire, Norman, Louisa, Rainville, Luc, Smith, Madison M, Thomas, Leif N, Torres-Valdés, Sinhué, Wood, Kevin R, MacKinnon, Jennifer A, Simmons, Harper L, Hargrove, John, Thomson, Jim, Peacock, Thomas, Alford, Matthew H, Barton, Benjamin I, Boury, Samuel, Brenner, Samuel D, Couto, Nicole, Danielson, Seth L, Fine, Elizabeth C, Graber, Hans C, Guthrie, John, Hopkins, Joanne E, Jayne, Steven R, Jeon, Chanhyung, Klenz, Thilo, Lee, Craig M, Lenn, Yueng-Djern, Lucas, Andrew J, Lund, Björn, Mahaffey, Claire, Norman, Louisa, Rainville, Luc, Smith, Madison M, Thomas, Leif N, Torres-Valdés, Sinhué, and Wood, Kevin R

Abstract

Unprecedented quantities of heat are entering the Pacific sector of the Arctic Ocean through Bering Strait, particularly during summer months. Though some heat is lost to the atmosphere during autumn cooling, a significant fraction of the incoming warm, salty water subducts (dives beneath) below a cooler fresher layer of near-surface water, subsequently extending hundreds of kilometers into the Beaufort Gyre. Upward turbulent mixing of these sub-surface pockets of heat is likely accelerating sea ice melt in the region. This Pacific-origin water brings both heat and unique biogeochemical properties, contributing to a changing Arctic ecosystem. However, our ability to understand or forecast the role of this incoming water mass has been hampered by lack of understanding of the physical processes controlling subduction and evolution of this this warm water. Crucially, the processes seen here occur at small horizontal scales not resolved by regional forecast models or climate simulations; new parameterizations must be developed that accurately represent the physics. Here we present novel high resolution observations showing the detailed process of subduction and initial evolution of warm Pacific-origin water in the southern Beaufort Gyre.

Published
2022

6. A warm jet in a cold ocean

Author

MacKinnon, Jennifer A., Simmons, Harper L., Hargrove, John, Thomson, Jim, Peacock, Thomas, Alford, Matthew H., Barton, Benjamin I., Boury, Samuel, Brenner, Samuel D., Couto, Nicole, Danielson, Seth L., Fine, Elizabeth C., Graber, Hans C., Guthrie, John, Hopkins, Joanne E., Jayne, Steven R., Jeon, Chanhyung, Klenz, Thilo, Lee, Craig M., Lenn, Yueng-Djern, Lucas, Andrew J., Lund, Björn, Mahaffey, Claire, Norman, Louisa, Rainville, Luc, Smith, Madison M., Thomas, Leif N., Torres-Valdés, Sinhué, Wood, Kevin R., MacKinnon, Jennifer A., Simmons, Harper L., Hargrove, John, Thomson, Jim, Peacock, Thomas, Alford, Matthew H., Barton, Benjamin I., Boury, Samuel, Brenner, Samuel D., Couto, Nicole, Danielson, Seth L., Fine, Elizabeth C., Graber, Hans C., Guthrie, John, Hopkins, Joanne E., Jayne, Steven R., Jeon, Chanhyung, Klenz, Thilo, Lee, Craig M., Lenn, Yueng-Djern, Lucas, Andrew J., Lund, Björn, Mahaffey, Claire, Norman, Louisa, Rainville, Luc, Smith, Madison M., Thomas, Leif N., Torres-Valdés, Sinhué, and Wood, Kevin R.

Abstract

Unprecedented quantities of heat are entering the Pacific sector of the Arctic Ocean through Bering Strait, particularly during summer months. Though some heat is lost to the atmosphere during autumn cooling, a significant fraction of the incoming warm, salty water subducts (dives beneath) below a cooler fresher layer of near-surface water, subsequently extending hundreds of kilometers into the Beaufort Gyre. Upward turbulent mixing of these sub-surface pockets of heat is likely accelerating sea ice melt in the region. This Pacific-origin water brings both heat and unique biogeochemical properties, contributing to a changing Arctic ecosystem. However, our ability to understand or forecast the role of this incoming water mass has been hampered by lack of understanding of the physical processes controlling subduction and evolution of this this warm water. Crucially, the processes seen here occur at small horizontal scales not resolved by regional forecast models or climate simulations; new parameterizations must be developed that accurately represent the physics. Here we present novel high resolution observations showing the detailed process of subduction and initial evolution of warm Pacific-origin water in the southern Beaufort Gyre.

Published
2022

7. Multi‐decadal environmental change in the Barents Sea recorded by seal teeth

Author

de la Vega, Camille, primary, Buchanan, Pearse J., additional, Tagliabue, Alessandro, additional, Hopkins, Joanne E., additional, Jeffreys, Rachel M., additional, Frie, Anne Kirstine, additional, Biuw, Martin, additional, Kershaw, Joanna, additional, Grecian, James, additional, Norman, Louisa, additional, Smout, Sophie, additional, Haug, Tore, additional, and Mahaffey, Claire, additional

Published
2022
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10. An Arctic Strait of Two Halves: The Changing Dynamics of Nutrient Uptake and Limitation Across the Fram Strait

Author

Tuerena, Robyn E., primary, Hopkins, Jo, additional, Buchanan, Pearse J., additional, Ganeshram, Raja S., additional, Norman, Louisa, additional, von Appen, Wilken‐Jon, additional, Tagliabue, Alessandro, additional, Doncila, Antonia, additional, Graeve, Martin, additional, Ludwichowski, Kai U., additional, Dodd, Paul A., additional, de la Vega, Camille, additional, Salter, Ian, additional, and Mahaffey, Claire, additional

Published
2021
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11. Nitrate assimilation and regeneration in the Barents Sea: insights from nitrate isotopes

Author

Tuerena, Robyn E., Hopkins, Joanne, Ganeshram, Raja S., Norman, Louisa, de la Vega, Camille, Jeffreys, Rachel, Mahaffey, Claire, Tuerena, Robyn E., Hopkins, Joanne, Ganeshram, Raja S., Norman, Louisa, de la Vega, Camille, Jeffreys, Rachel, and Mahaffey, Claire

Abstract

While the entire Arctic Ocean is warming rapidly, the Barents Sea in particular is experiencing significant warming and sea ice retreat. An increase in ocean heat transport from the Atlantic is causing the Barents Sea to be transformed from a cold, salinity-stratified system into a warmer, less-stratified Atlantic-dominated climate regime. Productivity in the Barents Sea shelf is fuelled by waters of Atlantic origin (AW) which are ultimately exported to the Arctic Basin. The consequences of this current regime shift on the nutrient characteristics of the Barents Sea are poorly defined. Here we use the stable isotopic ratios of nitrate (δ15N-NO3, δ18O-NO3) to determine the uptake and modification of AW nutrients in the Barents Sea. In summer months, phytoplankton consume nitrate, surface waters become nitrate depleted, and particulate nitrogen (δ15N-PN) reflects the AW nitrate source. The ammonification of organic matter in shallow sediments resupplies N to the water column and replenishes the nitrate inventory for the following season. Low δ18O-NO3 in the northern Barents Sea reveals that the nitrate in lower-temperature Arctic waters is > 80 % regenerated through seasonal nitrification. During on-shelf nutrient uptake and regeneration, there is no significant change to δ15N-NO3 or N*, suggesting that benthic denitrification does not impart an isotopic imprint on pelagic nitrate. Our results demonstrate that the Barents Sea is distinct from other Arctic shelves where benthic denitrification enriches δ15N-NO3 and decreases N*. As nutrients are efficiently recycled in the Barents Sea and there is no significant loss of N through benthic denitrification, changes to Barents Sea productivity are unlikely to alter N availability on shelf or the magnitude of N advected to the central Arctic Basin. However, we suggest that the AW nutrient source ultimately determines Barents Sea productivity and that changes to AW delivery have the potential to alter Barents Sea primary pro

Published
2021

12. A warm jet in a cold ocean

Author

MacKinnon, Jennifer A., Simmons, Harper L., Hargrove, John, Thomson, Jim, Peacock, Thomas, Alford, Matthew H., Barton, Benjamin I., Boury, Samuel, Brenner, Samuel D., Couto, Nicole, Danielson, Seth L., Fine, Elizabeth C., Graber, Hans C., Guthrie, John, Hopkins, Joanne E., Jayne, Steven R., Jeon, Chanhyung, Klenz, Thilo, Lee, Craig M., Lenn, Yueng-Djern, Lucas, Andrew J., Lund, Björn, Mahaffey, Claire, Norman, Louisa, Rainville, Luc, Smith, Madison M., Thomas, Leif N., Torres-Valdés, Sinhué, Wood, Kevin R., MacKinnon, Jennifer A., Simmons, Harper L., Hargrove, John, Thomson, Jim, Peacock, Thomas, Alford, Matthew H., Barton, Benjamin I., Boury, Samuel, Brenner, Samuel D., Couto, Nicole, Danielson, Seth L., Fine, Elizabeth C., Graber, Hans C., Guthrie, John, Hopkins, Joanne E., Jayne, Steven R., Jeon, Chanhyung, Klenz, Thilo, Lee, Craig M., Lenn, Yueng-Djern, Lucas, Andrew J., Lund, Björn, Mahaffey, Claire, Norman, Louisa, Rainville, Luc, Smith, Madison M., Thomas, Leif N., Torres-Valdés, Sinhué, and Wood, Kevin R.

Abstract

Unprecedented quantities of heat are entering the Pacific sector of the Arctic Ocean through Bering Strait, particularly during summer months. Though some heat is lost to the atmosphere during autumn cooling, a significant fraction of the incoming warm, salty water subducts (dives beneath) below a cooler fresher layer of near-surface water, subsequently extending hundreds of kilometers into the Beaufort Gyre. Upward turbulent mixing of these sub-surface pockets of heat is likely accelerating sea ice melt in the region. This Pacific-origin water brings both heat and unique biogeochemical properties, contributing to a changing Arctic ecosystem. However, our ability to understand or forecast the role of this incoming water mass has been hampered by lack of understanding of the physical processes controlling subduction and evolution of this this warm water. Crucially, the processes seen here occur at small horizontal scales not resolved by regional forecast models or climate simulations; new parameterizations must be developed that accurately represent the physics. Here we present novel high resolution observations showing the detailed process of subduction and initial evolution of warm Pacific-origin water in the southern Beaufort Gyre.

Published
2021

13. An Arctic Strait of two halves: the changing dynamics of nutrient uptake and limitation across the Fram Strait

Author

Tuerena, Robyn E., Hopkins, Jo, Buchanan, Pearse J., Ganeshram, Raja S., Norman, Louisa, Appen, Wilken‐Jon, Tagliabue, Alessandro, Doncila, Antonia, Graeve, Martin, Ludwichowski, Kai U., Dodd, Paul A., Vega, Camille, Salter, Ian, Mahaffey, Claire, Tuerena, Robyn E., Hopkins, Jo, Buchanan, Pearse J., Ganeshram, Raja S., Norman, Louisa, Appen, Wilken‐Jon, Tagliabue, Alessandro, Doncila, Antonia, Graeve, Martin, Ludwichowski, Kai U., Dodd, Paul A., Vega, Camille, Salter, Ian, and Mahaffey, Claire

Abstract

The hydrography of the Arctic Seas is being altered by ongoing climate change, with knock-on effects to nutrient dynamics and primary production. As the major pathway of exchange between the Arctic and the Atlantic, the Fram Strait hosts two distinct water masses in the upper water column, northward flowing warm and saline Atlantic Waters in the east, and southward flowing cold and fresh Polar Surface Water in the west. Here, we assess how physical processes control nutrient dynamics in the Fram Strait using nitrogen isotope data collected during 2016 and 2018. In Atlantic Waters, a weakly stratified water column and a shallow nitracline reduce nitrogen limitation. To the west, in Polar Surface Water, nitrogen limitation is greater because stronger stratification inhibits nutrient resupply from deeper water and lateral nitrate supply from central Arctic waters is low. A historical hindcast simulation of ocean biogeochemistry from 1970 to 2019 corroborates these findings and highlights a strong link between nitrate supply to Atlantic Waters and the depth of winter mixing, which shoaled during the simulation in response to a local reduction in sea-ice formation. Overall, we find that while the eastern Fram Strait currently experiences seasonal nutrient replenishment and high primary production, the loss of winter sea ice and continued atmospheric warming has the potential to inhibit deep winter mixing and limit primary production in the future.

Published
2021

16. Growth of microalgae using nitrate-rich brine wash from the water industry

Author

Ridley, Christian J.A., Parker, Brenda M., Norman, Louisa, Schlarb-Ridley, Beatrix, Dennis, Ross, Jamieson, Alexandra E., Clark, Daniel, Skill, Stephen C., Smith, Alison G., Davey, Matthew P., Ridley, Christian J.A., Parker, Brenda M., Norman, Louisa, Schlarb-Ridley, Beatrix, Dennis, Ross, Jamieson, Alexandra E., Clark, Daniel, Skill, Stephen C., Smith, Alison G., and Davey, Matthew P.

Abstract

Safe and accepted limits for nitrates in drinking water are exceeded in around one-third of the groundwater bodies in Europe. Whilst anion exchange (AEX) is an effective technology to strip nitrates, the regeneration of AEX resins using saturated sodium chloride (brine) results in a significant quantity of nitrate-rich saline waste, which is currently disposed of at a substantial cost to the water industry. The aim of this research was to evaluate the viability of using AEX brine wash as a nutrient source to support microalgal growth. Experiments were carried out at laboratory and pilot scales to test which algal species were able to grow on brine wash, to determine the optimal nitrate concentration within modified growth media, and to identify whether the origin of the brine wash affected the nitrate uptake potential. In small scale laboratory experiments, five marine algal species were able to grow in modified f/2 growth media containing nitrate sourced from the brine wash. Further experiments showed that three species could grow on the modified media at nitrate concentrations from 5 to 274 mg L−1. P. tricornutum could remediate up to 6.5 mg nitrate in 50 mL cultures in laboratory scale experiments, up to 570 mg at 10 L scale and 1700 mg at 100 L scale. We found that the origin of the brine wash did not significantly affect the growth of the cultures or the amount of nitrate removal from the modified media. The algal biomass could be used effectively in biogas production in small-scale trials, although with <10% the yield from P. tricornutum biomass from standard f/2 medium. Our results suggest that it may be possible to derive value from brine wash as a sustainable source of nitrate for the growth of microalgae in bulk after optimisation.

Published
2018

17. Nitrate assimilation and regeneration in the Barents Sea: insights from nitrogen isotopes.

Author

Tuerena, Robyn E., Hopkins, Joanne, Ganeshram, Raja S., Norman, Louisa, la Vega, Camille de, Jeffreys, Rachel, and Mahaffey, Claire

Subjects
NITROGEN isotopes, NITRATES, SEA ice, ISOTOPIC signatures, SEAS, NUTRIENT uptake, SEAWATER salinity
Abstract

While the entire Arctic Ocean is warming rapidly, the Barents Sea in particular is experiencing significant warming and sea ice retreat. An increase in ocean heat transport from the Atlantic is causing the Barents Sea to be transformed from a cold, salinity stratified system into a warmer, less-stratified Atlantic-dominated climate regime. Productivity in the Barents Sea shelf is fuelled by waters of Atlantic origin (AW), which are ultimately exported to the Arctic basin. The consequences of this current regime shift on the nutrient characteristics of the Barents Sea are poorly defined. Here we use the stable isotopic ratios of nitrate (δ15N-NO3, δ18O-NO3), to determine the uptake and modification of AW nutrients in the Barents Sea. In summer months, phytoplankton consume nitrate, surface waters become nitrate depleted, and particulate nitrogen (δ15N-PN) reflects the AW nitrate source. The ammonification of organic matter in shallow sediments resupplies N to the water column through the season. Low δ18O-NO3 in the northern Barents Sea reveals that the nitrate in lower temperature Arctic Waters is > 80 % regenerated through seasonal nitrification. During on shelf nutrient uptake and regeneration, there is no significant change to δ15N-NO3 or N*, suggesting benthic denitrification does not impart an isotopic imprint on pelagic nitrate. Our results demonstrate that the Barents Sea is distinct from other Arctic shelves, where coupled partial nitrification-denitrification enriches δ15N-NO3 and decreases N*. Our results suggest that any current or future changes to productivity on the Barents Sea shelf are unlikely to alter the magnitude or isotopic signature of nutrient supply exported to the central Arctic basin. However, we suggest that the AW nutrient source ultimately determines Barents Sea productivity and changes to this supply may alter Barents Sea primary production and subsequent nutrient supply to the central Arctic Ocean. [ABSTRACT FROM AUTHOR]

Published
2020
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38. L. S. D.

Author

NORMAN, LOUISA JULIA

Published
1864

41. BOCCACCIO.

Author

NORMAN, LOUISA JULIA

Published
1861

43. QUOTATIONS.

Author

NORMAN, LOUISA JULIA

Published
1865

44. Snow algae communities in Antarctica: metabolic and taxonomic composition

Author

Kevin K. Newsham, Louisa Norman, Freddy Bunbury, Lloyd S. Peck, Matthew P. Davey, Peter Convey, Bradford Kin Wai Loh, Alison G. Smith, Sian Stockton, Peter Sterk, María Huete-Ortega, Davey, Matthew P [0000-0002-5220-4174], Norman, Louisa [0000-0001-9720-4664], Sterk, Peter [0000-0003-1668-7778], Huete-Ortega, Maria [0000-0002-8746-5518], Loh, Bradford Kin Wai [0000-0002-7762-8539], Convey, Peter [0000-0001-8497-9903], Newsham, Kevin K [0000-0002-9108-0936], Smith, Alison G [0000-0001-6511-5704], and Apollo - University of Cambridge Repository

Subjects
0106 biological sciences, 0301 basic medicine, snow algae, Physiology, Antarctic Regions, Cell Count, Plant Science, 01 natural sciences, 03 medical and health sciences, Algae, Chloromonas, Snow, Spectroscopy, Fourier Transform Infrared, Ecosystem, Biomass, community composition, bacteria, Principal Component Analysis, biology, Full Paper, Ecology, cryophilic, Research, Chlamydomonas, fungi, Primary production, Species diversity, Eukaryota, Pigments, Biological, 15. Life on land, Full Papers, Eutrophication, biology.organism_classification, metabolomics, Lipids, Chlorella, 030104 developmental biology, metabarcoding, Antarctica, human activities, 010606 plant biology & botany
Abstract

Snow algae are found in snowfields across cold regions of the planet, forming highly visible red and green patches below and on the snow surface. In Antarctica, they contribute significantly to terrestrial net primary productivity due to the paucity of land plants, but our knowledge of these communities is limited. Here we provide the first description of the metabolic and species diversity of green and red snow algae communities from four locations in Ryder Bay (Adelaide Island, 68°S), Antarctic Peninsula. During the 2015 austral summer season, we collected samples to measure the metabolic composition of snow algae communities and determined the species composition of these communities using metabarcoding. Green communities were protein‐rich, had a high chlorophyll content and contained many metabolites associated with nitrogen and amino acid metabolism. Red communities had a higher carotenoid content and contained more metabolites associated with carbohydrate and fatty acid metabolism. Chloromonas, Chlamydomonas and Chlorella were found in green blooms but only Chloromonas was detected in red blooms. Both communities also contained bacteria, protists and fungi. These data show the complexity and variation within snow algae communities in Antarctica and provide initial insights into the contribution they make to ecosystem functioning.

Published
2019

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