Your search keyword '"John M. Doherty"' showing total 6 results

1. Climate‐Modulated Nutrient Conditions Along the Labrador Shelf: Evidence From Nitrogen Isotopes in a Six‐Hundred‐Year‐Old Crustose Coralline Alga

Author

Branwen Williams, John M. Doherty, Esme Kline, Walter H. Adey, and Benoit Thibodeau

Subjects

Atmospheric Science, Nutrient, Oceanography, Atlantic multidecadal oscillation, Paleontology, Climate change, sense organs, skin and connective tissue diseases, Crustose, Isotopes of nitrogen

Abstract

The impacts of climate change on north Atlantic nutrient chemistry remain poorly understood, as there exist a multitude of rapidly changing biological and physical drivers of nutrient conditions th...

Published

2021

2. Intra‐Valve Elemental Distributions in Arctic Marine Ostracodes: Implications for Mg/Ca and Sr/Ca Paleothermometry

Author

Baochun Zhou, Wenshen Xiao, Ho Lai Hilary Man, John M. Doherty, Christelle Not, Maximiliano Rodriguez, Benoit Thibodeau, and Rujian Wang

Subjects

Geophysics, Oceanography, biology, Arctic, Geochemistry and Petrology, Ostracod, biology.organism_classification, Geology

Published

2021

3. Environmental modulations of nutrient conditions in the Labrador Sea reconstructed from nitrogen isotopes in a six-hundred-year-old crustose coralline alga

Author

Branwen Williams, Esme Kline, Walter H. Adey, John M. Doherty, and Benoit Thibodeau

Subjects

Biogeochemical cycle, Nutrient, Oceanography, Environmental science, Crustose, Isotopes of nitrogen

Abstract

The climatological impacts on biogeochemical processes in the polar North Atlantic remain poorly understood, as there exist both biological and physical mechanisms that drive nutrient availability ...

Published

2020

4. Freshening, stratification and deep-water formation in the Nordic Seas during marine isotope stage 11

Author

Henning A. Bauch, Dirk V. Erler, Benoit Thibodeau, Yuet F. Ling, John M. Doherty, Christelle Not, and Adina Paytan

Subjects

Marine isotope stage, Archeology, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Holocene climatic optimum, Stratification (water), Geology, 010502 geochemistry & geophysics, 01 natural sciences, Marine Isotope Stage 11, Oceanography, 13. Climate action, Interglacial, Nordic Seas, 14. Life underwater, Glacial period, Hydrography, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

Highlights • Hydrography and convection reconstructed in the Nordic Seas during MIS 11. • Active convection in the Nordic Seas occurred during prolonged freshwater input. • Freshwater input does not always impede convection on interglacial timescales. • Onset of polar convection may have helped to sustain interglacial conditions. Abstract The Atlantic meridional overturning circulation (AMOC) is a critical element of Earth's climate system and it is currently weakening. While this weakening is frequently explained by freshwater-driven disruptions to deep-water formation, uncertainties about the impacts of prolonged freshening limit our capacity to predict its future state. For example, during the warm and unusually long marine isotope stage (MIS) 11 interglacial, ∼424 to 374 ka, several lines of evidence suggest that a strong AMOC persisted concomitant with fresher-than-present conditions in the Nordic Seas, challenging our current understanding of deep-water formation. Here, we present new foraminifer-bound nitrogen isotope data along with multiple additional geochemical reconstructions of upper-ocean hydrography in the Nordic Seas during this anomalous interval. Our data suggest that a weak summer stratification was driven by the prolonged upper-ocean accumulation of freshwater beginning at the onset of the climatic optimum, ∼410 to 407 ka, which could have helped precondition the region for deep-water formation. A box model constrained by paleo-proxy data additionally suggests that the density gradient between the subpolar North Atlantic and Nordic Seas was favorable for the onset of deep-water formation in the Nordic Seas during the climatic optimum. It is thus likely that the Nordic Seas became a locus of deep-water formation around this time. Enhanced northern-hemisphere heating driven by deep-water formation in the Nordic Seas may have been important for delaying glacial conditions, thereby driving the extended warming characteristic of MIS 11. Such findings may also be relevant for near-future changes under a relatively fresher high-latitude North Atlantic.

Published

2021

5. Cold Water in a Warm World: Investigating the Origin of the Nordic Seas' Unique Surface Properties During MIS 11

Author

John M. Doherty and Benoit Thibodeau

Subjects

Marine isotope stage, 010504 meteorology & atmospheric sciences, lcsh:QH1-199.5, Climate change, Ocean Engineering, Aquatic Science, lcsh:General. Including nature conservation, geographical distribution, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Paleoceanography, MIS 11, Glacial period, Meltwater, lcsh:Science, Global change, 0105 earth and related environmental sciences, Water Science and Technology, Global and Planetary Change, Surface waters, North Atlantic, Iceberg, Paleoceaongraphy, Interglacial, AMOC, lcsh:Q, Geology

Abstract

Surface waters in the Nordic Seas were colder and fresher throughout the marine isotope stage (MIS) 11 interglacial compared to present day. This has been previously attributed to the continuous delivery of freshwater sourced from large ice structures characteristic of the preceding glacial interval, MIS 12. While it is conventionally believed that high-latitude surface freshening can trigger a reduction of the Atlantic Meridional Overturning Circulation (AMOC), multiple lines of evidence suggest a vigorous AMOC despite elevated freshwater forcing in the Nordic Seas. Here, we review and reanalyze evidence for sea surface properties throughout the Nordic Seas and North Atlantic. We find that surface waters in the Nordic Seas experienced an unusually variable inception of interglacial temperature conditions with multiple high-magnitude cold excursions. While cold events in the North Atlantic were frequently associated with in situ meltwater deposition as reconstructed by ice-rafted debris, this proxy was virtually uncorrelated with cold events in the Nordic Seas. Additionally, stable nitrogen analysis revealed variable levels of nutrient utilization in the Nordic Seas’ surface layer throughout MIS 11. This may reflect a dynamic structure of the upper ocean concomitant with an intermittent rate of freshwater delivery. Based on this combination of evidence, we suggest that the colder and fresher surface layer in the Nordic Seas was supplied from higher latitudes, rather than from locally-sourced iceberg meltwater as is characteristic of North Atlantic forcing. Pairing proxy-based evidence with recent numerical simulations further decouples surface freshening in the Nordic Seas and Greenland meltwater input, discrediting Greenland as a source of freshwater to this region during the later phase of MIS 11. Because the origin of freshwater has implications for its rate of delivery, our study might help to explain the active AMOC despite surface freshening during MIS 11 and should be recognized when considering this interglacial as an analogue for near-future climate change scenarios.

Published

2018

6. THE FORAMINIFERAN BACULOGYPSINA SPHAERULATA AS AN INDICATOR OF WATER QUALITY IN GUAM

Author

Kiho Kim, John M. Doherty, Sergio Morales, and Jonathan D. Cybulski

Subjects

Oceanography, Baculogypsina sphaerulata, Environmental science, Water quality

Published

2016