Your search keyword '"Blaker, Adam T."' showing total 4 results

1. Chaotic Variability of the Atlantic Meridional Overturning Circulation at Subannual Time Scales.

Author

GERME, AGATHE, HIRSCHI, JOËL J.-M., BLAKER, ADAM T., and SINHA, BABLU

Subjects

ATLANTIC meridional overturning circulation, MESOSCALE eddies, SPATIAL variation, GEOSTROPHIC currents

Abstract

This study describes the intra-to interannual variability of the Atlantic meridional overturning circulation (AMOC) and the relative dynamical contributions to the total variability in an eddy-resolving 1/128 resolution ocean model. Based on a 53-yr-long hindcast and two 4-yr-long ensembles, we assess the total AMOC variability as well as the variability arising from small differences in the ocean initial state that rapidly imprints on the mesoscale eddy fields and subsequently on large-scale features. This initial-condition-dependent variability will henceforth be referred to as "chaotic" variability. We find that intra-annual AMOC fluctuations are mainly driven by the atmospheric forcing, with the chaotic variability fraction never exceeding 26% of the total variance in the whole meridional Atlantic domain. To understand the nature of the chaotic variability we decompose the AMOC (into its Ekman, geostrophic, barotropic, and residual components). The barotropic and geostrophic AMOC contributions exhibit strong, partly compensating fluctuations, which are linked to chaotic spatial variations of currents over topography. In the North Atlantic, the largest chaotic divergence of ensemble members is found around 248, 388, and 648N. At 26.58N, where the AMOC is monitored by the RAPID-MOCHA array, the chaotic fraction of the AMOC variability is 10%. This fraction is slightly overestimated with the reconstruction methodology as used in the observations (∼15%). This higher fraction of chaotic variability is due to the barotropic contribution not being completely captured by the monitoring system. We look at the strong AMOC decline observed in 2009/10 and find that the ensemble spread (our measure for chaotic variability) was not particularly large during this event. [ABSTRACT FROM AUTHOR]

Published

2022

2. Evaluating the physical and biogeochemical state of the global ocean component of UKESM1 in CMIP6 historical simulations.

Author

Yool, Andrew, Palmiéri, Julien, Jones, Colin G., de Mora, Lee, Kuhlbrodt, Till, Popova, Ekatarina E., Nurser, A. J. George, Hirschi, Joel, Blaker, Adam T., Coward, Andrew C., Blockley, Edward W., and Sellar, Alistair A.

Subjects

GREENHOUSE effect, CARBON dioxide sinks, OCEAN, MARINE productivity, ATMOSPHERIC models

Abstract

The ocean plays a key role in modulating the climate of the Earth system (ES). At the present time it is also a major sink both for the carbon dioxide (CO2) released by human activities and for the excess heat driven by the resulting atmospheric greenhouse effect. Understanding the ocean's role in these processes is critical for model projections of future change and its potential impacts on human societies. A necessary first step in assessing the credibility of such future projections is an evaluation of their performance against the present state of the ocean. Here we use a range of observational fields to validate the physical and biogeochemical performance of the ocean component of UKESM1, a new Earth system model (ESM) for CMIP6 built upon the HadGEM3-GC3.1 physical climate model. Analysis focuses on the realism of the ocean's physical state and circulation, its key elemental cycles, and its marine productivity. UKESM1 generally performs well across a broad spectrum of properties, but it exhibits a number of notable biases. Physically, these include a global warm bias inherited from model spin-up, excess northern sea ice but insufficient southern sea ice and sluggish interior circulation. Biogeochemical biases found include shallow remineralization of sinking organic matter, excessive iron stress in regions such as the equatorial Pacific, and generally lower surface alkalinity that results in decreased surface and interior dissolved inorganic carbon (DIC) concentrations. The mechanisms driving these biases are explored to identify consequences for the behaviour of UKESM1 under future climate change scenarios and avenues for model improvement. Finally, across key biogeochemical properties, UKESM1 improves in performance relative to its CMIP5 precursor and performs well alongside its fellow members of the CMIP6 ensemble. [ABSTRACT FROM AUTHOR]

Published

2021

3. Evaluating the physical and biogeochemical state of the global ocean component of UKESM1 in CMIP6 Historical simulations.

Author

Yool, Andrew, Palmiéri, Julien, Jones, Colin G., de Mora, Lee, Kuhlbrodt, Till, Popova, Ekatarina E., Nurser, A. J. George, Hirschi, Joel, Blaker, Adam T., Coward, Andrew C., Blockley, Edward W., and Sellar, Alistair A.

Subjects

GREENHOUSE effect, CARBON dioxide sinks, OCEAN, PHYSICAL mobility, MARINE productivity

Abstract

The ocean plays a key role in modulating the climate of the Earth system (ES). At the present time it is also a major sink both for the carbon dioxide (CO2) released by human activities as well as for the excess heat driven by the resulting atmospheric greenhouse effect. Understanding the ocean's role in these processes is critical for model projections of future change and its potential impacts on human societies. A necessary first step in assessing the credibility of such future projections is an evaluation of their performance against the present state of the ocean. Here we use a range of observational properties to validate the physical and biogeochemical performance of the ocean component of UKESM1, a new Earth system (ESM) for CMIP6 built upon the HadGEM3 physical climate model. Analysis focuses on the realism of the ocean's physical state and circulation, its key elemental cycles, and its marine productivity. UKESM1 generally performs well across a broad spectrum of properties, but it exhibits a number of notable biases. Physically, these include a global warm bias inherited from model spin-up, excess northern sea-ice but insufficient southern sea-ice, and sluggish interior circulation. Biogeochemical biases found include shallow remineralisation of sinking organic matter, excessive iron stress in regions such as the Equatorial Pacific, and generally lower surface alkalinity that results in decreased surface and interior dissolved inorganic carbon (DIC) concentrations. The mechanisms driving these biases are explored to identify consequences for the behaviour of UKESM1 under future climate scenarios, and avenues for model improvement. Finally, across key biogeochemical properties, UKESM1 improves in performance relative to its CMIP5 precursor, and compares favourably to fellow members of the CMIP6 ensemble. [ABSTRACT FROM AUTHOR]

Published

2020

4. Loop Current Variability as Trigger of Coherent Gulf Stream Transport Anomalies.

Author

Hirschi, Joël J.-M., Frajka-Williams, Eleanor, Blaker, Adam T., Sinha, Bablu, Coward, Andrew, Hyder, Pat, Biastoch, Arne, Böning, Claus, Barnier, Bernard, Penduff, Thierry, Garcia, Ixetl, Fransner, Filippa, and Madec, Gurvan

Subjects

GULF Stream, STRAITS, OCEAN dynamics, BAYS, OCEAN circulation

Abstract

Satellite observations and output from a high-resolution ocean model are used to investigate how the Loop Current in the Gulf of Mexico affects the Gulf Stream transport through the Florida Straits. We find that the expansion (contraction) of the Loop Current leads to lower (higher) transports through the Straits of Florida. The associated surface velocity anomalies are coherent from the southwestern tip of Florida to Cape Hatteras. A simple continuity-based argument can be used to explain the link between the Loop Current and the downstream Gulf Stream transport: as the Loop Current lengthens (shortens) its path in the Gulf of Mexico, the flow out of the Gulf decreases (increases). Anomalies in the surface velocity field are first seen to the southwest of Florida and within 4 weeks propagate through the Florida Straits up to Cape Hatteras and into the Gulf Stream Extension. In both the observations and the model this propagation can be seen as pulses in the surface velocities. We estimate that the Loop Current variability can be linked to a variability of several Sverdrups (1Sv = 106 m3 s−1) through the Florida Straits. The exact timing of the Loop Current variability is largely unpredictable beyond a few weeks and its variability is therefore likely a major contributor to the chaotic/intrinsic variability of the Gulf Stream. However, the time lag between the Loop Current and the flow downstream of the Gulf of Mexico means that if a lengthening/shortening of the Loop Current is observed this introduces some predictability in the downstream flow for a few weeks. [ABSTRACT FROM AUTHOR]

Published

2019