Your search keyword '"James W. Hurrell"' showing total 21 results

1. Indicator Patterns of Forced Change Learned by an Artificial Neural Network

Author

Elizabeth A. Barnes, Benjamin Toms, James W. Hurrell, Imme Ebert‐Uphoff, Chuck Anderson, and David Anderson

Subjects

Physical geography, GB3-5030, Oceanography, GC1-1581

Abstract

Abstract Many problems in climate science require the identification of signals obscured by both the “noise” of internal climate variability and differences across models. Following previous work, we train an artificial neural network (ANN) to predict the year of a given map of annual‐mean temperature (or precipitation) from forced climate model simulations. This prediction task requires the ANN to learn forced patterns of change amidst a background of climate noise and model differences. We then apply a neural network visualization technique (layerwise relevance propagation) to visualize the spatial patterns that lead the ANN to successfully predict the year. These spatial patterns thus serve as “reliable indicators” of the forced change. The architecture of the ANN is chosen such that these indicators vary in time, thus capturing the evolving nature of regional signals of change. Results are compared to those of more standard approaches like signal‐to‐noise ratios and multilinear regression in order to gain intuition about the reliable indicators identified by the ANN. We then apply an additional visualization tool (backward optimization) to highlight where disagreements in simulated and observed patterns of change are most important for the prediction of the year. This work demonstrates that ANNs and their visualization tools make a powerful pair for extracting climate patterns of forced change.

Published

2020

2. Climate controls on marine ecosystems and fish populations

Author

Juergen Alheit, Andrew Bakun, David L. Mackas, James E. Overland, James W. Hurrell, and Arthur J. Miller

Subjects

La Niña, Disturbance (ecology), Climatology, Ocean current, Climate change, Environmental science, Regime shift, Marine ecosystem, Ecosystem, Aquatic Science, Oceanography, Ecology, Evolution, Behavior and Systematics, Pacific decadal oscillation

Abstract

This paper discusses large-scale climate variability for several marine ecosystems and suggests types of ecosystem responses to climate change. Our analysis of observations and model results for the Pacific and Atlantic Oceans concludes that most climate variability is accounted for by the combination of intermittent 1–2 year duration events, e.g. the cumulative effect of monthly weather anomalies or the more organized El Nino/La Nina, plus broad-band “red noise” intrinsic variability operating at decadal and longer timescales. While ocean processes such as heat storage and lags due to ocean circulation provide some multi-year memory to the climate system, basic understanding of the mechanisms resulting in observed large decadal variability is lacking and forces the adoption of a “stochastic or red noise” conceptual model of low frequency variability at the present time. Thus we conclude that decadal events with rapid shifts and major departures from climatic means will occur, but their timing cannot be forecast. The responses to climate by biological systems are diverse in character because intervening processes introduce a variety of amplifications, time lags, feedbacks, and non-linearities. Decadal ecosystem variability can involve a variety of climate to ecosystem transfer functions. These can be expected to convert red noise of the physical system to redder (lower frequency) noise of the biological response, but can also convert climatic red noise to more abrupt and discontinuous biological shifts, transient climatic disturbance to prolonged ecosystem recovery, and perhaps transient disturbance to sustained ecosystem regimes. All of these ecosystem response characteristics are likely to be active for at least some locations and time periods, leading to a mix of slow fluctuations, prolonged trends, and step-like changes in ecosystems and fish populations in response to climate change. Climate variables such as temperatures and winds can have strong teleconnections (large spatial covariability) within individual ocean basins, but between-basin teleconnections, and potential climate-driven biological synchrony over several decades, are usually much weaker and a highly intermittent function of the conditions prevailing at the time within the adjoining basins. As noted in the recent IPCC 4th Assessment Report, a warming trend of ocean surface layers and loss of regional sea ice is likely before 2030, due to addition of greenhouse gases. Combined with large continuing natural climate variability, this will stress ecosystems in ways that they have not encountered for at least 100s of years.

Published

2010

3. North Atlantic climate variability: The role of the North Atlantic Oscillation

Author

Clara Deser and James W. Hurrell

Subjects

geography, geography.geographical_feature_category, Atmospheric circulation, Northern Hemisphere, Aquatic Science, Oceanography, Sea surface temperature, Atlantic Equatorial mode, Ocean gyre, North Atlantic oscillation, Climatology, Extratropical cyclone, Marine ecosystem, Ecology, Evolution, Behavior and Systematics

Abstract

Marine ecosystems are undergoing rapid change at local and global scales. To understand these changes, including the relative roles of natural variability and anthropogenic effects, and to predict the future state of marine ecosystems requires quantitative understanding of the physics, biogeochemistry and ecology of oceanic systems at mechanistic levels. Central to this understanding is the role played by dominant patterns or “modes” of atmospheric and oceanic variability, which orchestrate coherent variations in climate over large regions with profound impacts on ecosystems. We review the spatial structure of extratropical climate variability over the Northern Hemisphere and, specifically, focus on modes of climate variability over the extratropical North Atlantic. A leading pattern of weather and climate variability over the Northern Hemisphere is the North Atlantic Oscillation (NAO). The NAO refers to a redistribution of atmospheric mass between the Arctic and the subtropical Atlantic, and swings from one phase to another producing large changes in surface air temperature, winds, storminess and precipitation over the Atlantic as well as the adjacent continents. The NAO also affects the ocean through changes in heat content, gyre circulations, mixed layer depth, salinity, high latitude deep water formation and sea ice cover. Thus, indices of the NAO have become widely used to document and understand how this mode of variability alters the structure and functioning of marine ecosystems. There is no unique way, however, to define the NAO. Several approaches are discussed including both linear (e.g., principal component analysis) and nonlinear (e.g., cluster analysis) techniques. The former, which have been most widely used, assume preferred atmospheric circulation states come in pairs, in which anomalies of opposite polarity have the same spatial structure. In contrast, nonlinear techniques search for recurrent patterns of a specific amplitude and sign. They reveal, for instance, spatial asymmetries between different phases of the NAO that are likely important for ecological studies. It also follows that there is no universally accepted index to describe the temporal evolution of the NAO. Several of the most common measures are presented and compared. All reveal that there is no preferred time scale of variability for the NAO: large changes occur from one winter to the next and from one decade to the next. There is also a large amount of within-season variability in the patterns of atmospheric circulation of the North Atlantic, so that most winters cannot be characterized solely by a canonical NAO structure. A better understanding of how the NAO responds to external forcing, including sea surface temperature changes in the tropics, stratospheric influences, and increasing greenhouse gas concentrations, is crucial to the current debate on climate variability and change.

Published

2009

4. Atlantic Climate Variability and Predictability: A CLIVAR Perspective

Author

James W. Hurrell, R. A. Clarke, Yochanan Kushnir, Alberto R. Piola, Antonio J. Busalacchi, William E. Johns, Robert R. Dickson, Chris J. C. Reason, Gilles Reverdin, Thomas L. Delworth, Friedrich A Schott, Ilana Wainer, Cecilie Mauritzen, Daniel G. Wright, Klaus Peter Koltermann, Rowan Sutton, Martin Visbeck, David P. Marshall, and Michael S. McCartney

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Tropical Atlantic Variability, 010505 oceanography, Ocean current, MUDANÇA CLIMÁTICA, Climate change, 01 natural sciences, Oceanography, 13. Climate action, North Atlantic oscillation, Climatology, Atlantic multidecadal oscillation, Environmental science, Thermohaline circulation, Predictability, 0105 earth and related environmental sciences, Teleconnection

Abstract

Three interrelated climate phenomena are at the center of the Climate Variability and Predictability (CLIVAR) Atlantic research: tropical Atlantic variability (TAV), the North Atlantic Oscillation (NAO), and the Atlantic meridional overturning circulation (MOC). These phenomena produce a myriad of impacts on society and the environment on seasonal, interannual, and longer time scales through variability manifest as coherent fluctuations in ocean and land temperature, rainfall, and extreme events. Improved understanding of this variability is essential for assessing the likely range of future climate fluctuations and the extent to which they may be predictable, as well as understanding the potential impact of human-induced climate change. CLIVAR is addressing these issues through prioritized and integrated plans for short-term and sustained observations, basin-scale reanalysis, and modeling and theoretical investigations of the coupled Atlantic climate system and its links to remote regions. In this paper, a brief review of the state of understanding of Atlantic climate variability and achievements to date is provided. Considerable discussion is given to future challenges related to building and sustaining observing systems, developing synthesis strategies to support understanding and attribution of observed change, understanding sources of predictability, and developing prediction systems in order to meet the scientific objectives of the CLIVAR Atlantic program.

Published

2006

5. Pacific Interdecadal Climate Variability: Linkages between the Tropics and the North Pacific during Boreal Winter since 1900

Author

James W. Hurrell, Adam S. Phillips, and Clara Deser

Subjects

Atmospheric Science, Sea surface temperature, Oceanography, Geography, Climatology, Interdecadal Pacific Oscillation, Tropical climate, Tropical wave, Tropical rain belt, South Pacific convergence zone, Pacific decadal oscillation, Tropical rainforest climate

Abstract

This study examines the tropical linkages to interdecadal climate fluctuations over the North Pacific during boreal winter through a comprehensive and physically based analysis of a wide variety of observational datasets spanning the twentieth century. Simple difference maps between epochs of high sea level pressure over the North Pacific (1900-24 and 1947-76) and epochs of low pressure (1925-46 and 1977-97) are presented for numerous climate variables throughout the tropical Indo-Pacific region, including rainfall, cloudiness, sea surface temperature (SST), and sea level pressure. The results support the notion that the Tropics play a key role in North Pacific interdecadal climate variability. In particular, SST anomalies in the tropical Indian Ocean and southeast Pacific Ocean, rainfall and cloudiness anomalies in the vicinity of the South Pacific convergence zone, stratus clouds in the eastern tropical Pacific, and sea level pressure differences between the tropical southeast Pacific and Indian Oceans all exhibit prominent interdecadal fluctuations that are coherent with those in sea level pressure over the North Pacific. The spatial patterns of the interdecadal tropical climate anomalies are compared with those associated with ENSO, a predominantly interannual phenomenon; in general, the two are similar with some differences in relative spatial emphasis. Finally, a published 194-yr coral record in the western tropical Indian Ocean is shown to compare favorably with the twentieth-century instrumental records, indicating the potential for extending knowledge of tropical interdecadal climate variability to earlier time periods.

Published

2004

6. Twentieth century North Atlantic climate change. Part II: Understanding the effect of Indian Ocean warming

Author

Gary T. Bates, James W. Hurrell, Adam S. Phillips, Taiyi Xu, and Martin P. Hoerling

Subjects

Atmospheric Science, Sea surface temperature, Oceanography, North Atlantic oscillation, Climatology, Atlantic multidecadal oscillation, Northern Hemisphere, Extratropical cyclone, Environmental science, Climate change, Thermohaline circulation, Storm track

Abstract

Ensembles of atmospheric general circulation model (AGCM) experiments are used in an effort to understand the boreal winter Northern Hemisphere (NH) extratropical climate response to the observed warming of tropical sea surface temperatures (SSTs) over the last half of the twentieth Century. Specifically, we inquire about the origins of unusual, if not unprecedented, changes in the wintertime North Atlantic and European climate that are well described by a linear trend in most indices of the North Atlantic Oscillation (NAO). The simulated NH atmospheric response to the linear trend component of tropic-wide SST change since 1950 projects strongly onto the positive polarity of the NAO and is a hemispheric pattern distinguished by decreased (increased) Arctic (middle latitude) sea level pressure. Progressive warming of the Indian Ocean is the principal contributor to this wintertime extratropical response, as shown through additional AGCM ensembles forced with only the SST trend in that sector. The Indian Ocean influence is further established through the reproducibility of results across three different models forced with identical, idealized patterns of the observed warming. Examination of the transient atmospheric adjustment to a sudden “switch-on” of an Indian Ocean SST anomaly reveals that the North Atlantic response is not consistent with linear theory and most likely involves synoptic eddy feedbacks associated with changes in the North Atlantic storm track. The tropical SST control exerted over twentieth century regional climate underlies the importance of determining the future course of tropical SST for regional climate change and its uncertainty. Better understanding of the extratropical responses to different, plausible trajectories of the tropical oceans is key to such efforts.

Published

2004

7. North Atlantic climate variability: phenomena, impacts and mechanisms

Author

Yochanan Kushnir, Arnaud Czaja, John Marshall, Ping Chang, David S. Battisti, Michael S. McCartney, James W. Hurrell, Robert R. Dickson, Martin Visbeck, and Ramalingam Saravanan

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Tropical Atlantic Variability, Tropical Atlantic, 010502 geochemistry & geophysics, 01 natural sciences, Atlantic Equatorial mode, Oceanography, 13. Climate action, North Atlantic oscillation, Climatology, Atlantic multidecadal oscillation, Environmental science, Climate variation, 0105 earth and related environmental sciences

Abstract

Variability of the North Atlantic Oscillation and the Tropical Atlantic dominate the climate of the North Atlantic sector, the underlying ocean and surrounding continents on interannual to decadal time scales. Here we review these phenomena, their climatic impacts and our present state of understanding of their underlying cause. Copyright © 2001 Royal Meteorological Society.

Published

2001

8. The Arctic Ocean Response to the North Atlantic Oscillation

Author

B. Adlandsvik, Jens Meincke, Robert R. Dickson, G. V. Alekseev, Timothy J. Osborn, Johan Blindheim, James W. Hurrell, Torgny Vinje, Wieslaw Maslowski, and Oceanography

Subjects

Arctic sea ice decline, Atmospheric Science, geography, geography.geographical_feature_category, Arctic dipole anomaly, Forcing (mathematics), Arctic ice pack, Oceanography, North Atlantic oscillation, Climatology, Sea ice, Environmental science, Storm track, Precipitation

Abstract

The climatically sensitive zone of the Arctic Ocean lies squarely within the domain of the North Atlantic oscillation (NAO), one of the most robust recurrent modes of atmospheric behavior. However, the specific response of the Arctic to annual and longer-period changes in the NAO is not well understood. Here that response is investigated using a wide range of datasets, but concentrating on the winter season when the forcing is maximal and on the postwar period, which includes the most comprehensive instrumental record. This period also contains the largest recorded low-frequency change in NAO activity—from its most persistent and extreme low index phase in the 1960s to its most persistent and extreme high index phase in the late 1980s/early 1990s. This longperiod shift between contrasting NAO extrema was accompanied, among other changes, by an intensifying storm track through the Nordic Seas, a radical increase in the atmospheric moisture flux convergence and winter precipitation in this sector, an increase in the amount and temperature of the Atlantic water inflow to the Arctic Ocean via both inflow branches (Barents Sea Throughflow and West Spitsbergen Current), a decrease in the late-winter extent of sea ice throughout the European subarctic, and (temporarily at least) an increase in the annual volume flux of ice from the Fram Strait.

Published

2000

9. [Untitled]

Author

James W. Hurrell and Harry van Loon

Subjects

Atmospheric Science, Global and Planetary Change, North Atlantic Deep Water, Northern Hemisphere, Gulf Stream, Atlantic Equatorial mode, Oceanography, North Atlantic oscillation, Climatology, Storm track, Thermohaline circulation, sense organs, Icelandic Low, Geology

Abstract

Large changes in the wintertime atmospheric circulation have occurred over the past two decades over the ocean basins of the Northern Hemisphere, and these changes have had a profound effect on regional distributions of surface temperature and precipitation. The changes over the North Pacific have been well documented and have contributed to increases in temperatures across Alaska and much of western North America and to decreases in sea surface temperatures over the central North Pacific. The variations over the North Atlantic are related to changes in the North Atlantic Oscillation (NAO). Over the past 130 years, the NAO has exhibited considerable variability at quasi-biennial and quasi-decadal time scales, and the latter have become especially pronounced the second half of this century. Since 1980, the NAO has tended to remain in one extreme phase and has accounted for a substantial part of the observed wintertime surface warming over Europe and downstream over Eurasia and cooling in the northwest Atlantic. Anomalies in precipitation, including dry wintertime conditions over southern Europe and the Mediterranean and wetter-than-normal conditions over northern Europe and Scandinavia since 1980, are also linked to the behavior of the NAO. Changes in the monthly mean flow over the Atlantic are accompanied by a northward shift in the storm tracks and associated synoptic eddy activity, and these changes help to reinforce and maintain the anomalous mean circulation in the upper troposphere. It is important that studies of trends in local climate records, such as those from high elevation sites, recognize the presence of strong regional patterns of change associated with phenomena like the NAO.

Published

1997

10. Influence of variations in extratropical wintertime teleconnections on northern hemisphere temperature

Author

James W. Hurrell

Subjects

geography, geography.geographical_feature_category, Atmospheric circulation, Anomaly (natural sciences), Northern Hemisphere, Global change, Geophysics, Oceanography, North Atlantic oscillation, Climatology, Extratropical cyclone, General Earth and Planetary Sciences, Environmental science, Oceanic basin, Teleconnection

Abstract

Pronounced changes in the wintertime atmospheric circulation have occurred since the mid-1970s over the ocean basins of the Northern Hemisphere, and these changes have had a profound effect on surface temperatures. The variations over the North Atlantic are related to changes in the North Atlantic Oscillation (NAO), while the changes over the North Pacific are linked to the tropics and involve variations in the Aleutian low with teleconnections downstream over North America. Multivariate linear regression is used to show that nearly all of the cooling in the northwest Atlantic and the warming across Europe and downstream over Eurasia since the mid-1970s results from the changes in the NAO, and the NAO accounts for 31% of the hemispheric interannual variance over the past 60 winters. Over the Pacific basin and North America, the temperature anomalies result in part from tropical forcing associated with the El Nino-Southern Oscillation phenomenon but with important feedbacks in the extratropics. The changes in circulation over the past two decades have resulted in a surface temperature anomaly pattern of warmth over the continents and coolness over the oceans. This pattern of temperature change has amplified the observed hemispheric-averaged warming because of it interaction with land and ocean;more » temperature changes are larger over land compared to the oceans because of the small heat capacity of the former. 13 refs., 5 fig., 2 tab.« less

Published

1996

11. Decadal Trends in the North Atlantic Oscillation: Regional Temperatures and Precipitation

Author

James W. Hurrell

Subjects

Multidisciplinary, 010504 meteorology & atmospheric sciences, Tropical Atlantic Variability, North Atlantic Deep Water, 010502 geochemistry & geophysics, 01 natural sciences, Gulf Stream, Oceanography, Atlantic Equatorial mode, 13. Climate action, North Atlantic oscillation, Atlantic multidecadal oscillation, Icelandic Low, Geology, 0105 earth and related environmental sciences, Azores High

Abstract

Greenland ice-core data have revealed large decadal climate variations over the North Atlantic that can be related to a major source of low-frequency variability, the North Atlantic Oscillation. Over the past decade, the Oscillation has remained in one extreme phase during the winters, contributing significantly to the recent wintertime warmth across Europe and to cold conditions in the northwest Atlantic. An evaluation of the atmospheric moisture budget reveals coherent large-scale changes since 1980 that are linked to recent dry conditions over southern Europe and the Mediterranean, whereas northern Europe and parts of Scandinavia have generally experienced wetter than normal conditions.

Published

1995

12. Decadal atmosphere-ocean variations in the Pacific

Author

Kevin E. Trenberth and James W. Hurrell

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Atmospheric circulation, Ocean current, North Pacific High, Wind stress, Pacific–North American teleconnection pattern, North Pacific Oscillation, Oceanography, Climatology, Sea ice, Environmental science, Pacific decadal oscillation

Abstract

Considerable evidence has emerged of a sub- stantial decade-long change in the north Pacific atmo- sphere and ocean lasting from about 1976 to 1988. Ob- served significant changes in the atmospheric circula- tion throughout the troposphere revealed a deeper and eastward shifted Aleutian low pressure system in the winter half year which advected warmer and moister air along the west coast of North America and into Alaska and colder air over the north Pacific. Conse- quently, there were increases in temperatures and sea surface temperatures (SSTs) along the west coast of North America and Alaska but decreases in SSTs over the central north Pacific, as well as changes in coastal rainfall and streamflow, and decreases in sea ice in the Bering Sea. Associated changes occurred in the surface wind stress, and, by inference, in the Sverdrup trans- port in the north Pacific Ocean. Changes in the month- ly mean flow were accompanied by a southward shift in the storm tracks and associated synoptic eddy activi- ty and in the surface ocean sensible and latent heat fluxes. In addition to the changes in the physical envi- ronment, the deeper Aleutian low increased the nu- trient supply as seen through increases in total chloro- phyll in the water column, phytoplankton and zoo- plankton. These changes, along with the altered ocean currents and temperatures, changed the migration pat- terns and increased the stock of many fish species. A north Pacific (NP) index is defined to measure the de- cadal variations, and the temporal variability of the in- dex is explored on daily, annual, interannual and de- cadal time scales. The dominant atmosphere-ocean re- lation in the north Pacific is one where atmospheric changes lead SSTs by one to two months. However, strong ties are revealed with events in the tropical Pa- cific, with changes in tropical Pacific SSTs leading SSTs in the north Pacific by three months. Changes in the storm tracks in the north Pacific help to reinforce and maintain the anomalous circulation in the upper tro

Published

1994

13. A modulation of the atmospheric annual cycle in the Southern Hemisphere

Author

Harry van Loon and James W. Hurrell

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, 010505 oceanography, Sudden stratospheric warming, Oceanography, Annual cycle, 01 natural sciences, Latitude, Troposphere, Polar vortex, Climatology, Middle latitudes, Environmental science, Stratosphere, Southern Hemisphere, 0105 earth and related environmental sciences

Abstract

The annual cycle in pressure and winds at the middle and high latitudes of the Southern Hemisphere changed appreciably in the troposphere after the late 1970s. Before that time, its major component over most of the southern oceans and the Antarctic was a semiannual oscillation (SAO) which had maxima in the equinoctial seasons over the middle latitude oceans and in the solstitial seasons over the Antarctic south of 60°S. The SAO weakened after the late 1970s because of significant decadal changes in the monthly means primarily during the second half of the year. A result was that the polar vortex in the troposphere, which normally weakens after a peak in late September and early October, remained strong into November, and the breakdown of the stratospheric polar vortex was similarly delayed. The pressure in the circumpolar trough in the 1980s was generally lower than in the 1970s, which is similar to a documented change in the North Pacific during northern winter. We suggest that the changes in the SAO, the circumpolar trough, and the polar vortex are related to the concurrent rise of sea surface temperatures at low latitudes. The delayed breakdown of the polar vortex in the troposphere and lower stratosphere which happened after the late 1970s was coincident with the beginning of the ozone deficit in the Antarctic spring. This points to a strong dynamical influence on ozone amounts. DOI: 10.1034/j.1600-0870.1994.t01-1-00007.x

Published

2011

14. The North Atlantic Oscillation

Author

Yochanan Kushnir, Martin Visbeck, and James W. Hurrell

Subjects

Multidisciplinary, 010504 meteorology & atmospheric sciences, 0207 environmental engineering, 02 engineering and technology, Subtropics, 01 natural sciences, The arctic, Gulf Stream, Atlantic Equatorial mode, Oceanography, Geography, 13. Climate action, North Atlantic oscillation, Atlantic multidecadal oscillation, Natural variability, 020701 environmental engineering, 0105 earth and related environmental sciences, Atlantic World

Abstract

The North Atlantic Oscillation (NAO) dictates climate variability from the eastern seaboard of the United States to Siberia and from the Arctic to the subtropical Atlantic, especially during winter. It strongly affects agricultural yields, water management, fish inventories, and terrestrial ecology. In their Perspective, Hurrell, Kushnir, and Visbeck report recent research into the NAO discussed at an American Geophysical Union Chapman Conference at the end of 2000. Much remains to be learned about the NAO, but it seems increasingly less likely that natural variability is the cause for the recent upward NAO trend.

Published

2001

15. CLIMATE VARIABILITY | North Atlantic and Arctic Oscillation

Author

James W. Hurrell

Subjects

Oceanography, Arctic oscillation, Environmental science

Published

2003

16. The North Atlantic Oscillation: Climatic Significance and Environmental Impact

Author

James W. Hurrell, Geir Ottersen, Yochanan Kushnir, and Martin Visbeck

Subjects

Oceanography, North Atlantic oscillation, Environmental science

Published

2003

17. Climatic variability over the North Atlantic

Author

James W. Hurrell, Chris K. Folland, and Marten P. Hoerling

Subjects

Gulf Stream, Atlantic Equatorial mode, Oceanography, Shutdown of thermohaline circulation, North Atlantic oscillation, Atmospheric circulation, Climatology, Atlantic multidecadal oscillation, Environmental science, Thermohaline circulation, Physical oceanography

Abstract

This chapter begins with a broad review of the North Atlantic Oscillation (NAO) and the mechanisms that might influence its phase and amplitude on decadal and longer timescales. New results are presented which suggest an important role for tropical ocean forcing of the unprecedented trend in the wintertime NAO index over the past several decades. We conclude with a brief discussion of a significant recent change in the pattern of the summertime atmospheric circulation over the North Atlantic.

Published

2002

18. The North Atlantic Oscillation: past, present, and future

Author

Lorenzo M. Polvani, Martin Visbeck, Heidi Cullen, and James W. Hurrell

Subjects

Multidisciplinary, Oceanography, Geography, North Atlantic oscillation, Range (biology), Subtropics, From the Academy

Abstract

The climate of the Atlantic sector exhibits considerable variability on a wide range of time scales. A substantial portion is associated with the North Atlantic Oscillation (NAO), a hemispheric meridional oscillation in atmospheric mass with centers of action near Iceland and over the subtropical Atlantic. NAO-related impacts on winter climate extend from Florida to Greenland and from northwestern Africa over Europe far into northern Asia. Over the last 3 decades, the phase of the NAO has been shifting from mostly negative to mostly positive index values. Much remains to be learned about the mechanisms that produce such low frequency changes in the North Atlantic climate, but it seems increasingly likely that human activities are playing a significant role.

Published

2001

19. Tropical Origins for Recent North Atlantic Climate Change

Author

James W. Hurrell, Martin P. Hoerling, and Taiyi Xu

Subjects

Multidisciplinary, 010504 meteorology & atmospheric sciences, North Atlantic Deep Water, Tropical wave, 010502 geochemistry & geophysics, 01 natural sciences, Gulf Stream, Sea surface temperature, Atlantic Equatorial mode, Oceanography, 13. Climate action, North Atlantic oscillation, Atlantic multidecadal oscillation, Environmental science, Thermohaline circulation, 0105 earth and related environmental sciences

Abstract

Evidence is presented that North Atlantic climate change since 1950 is linked to a progressive warming of tropical sea surface temperatures, especially over the Indian and Pacific Oceans. The ocean changes alter the pattern and magnitude of tropical rainfall and atmospheric heating, the atmospheric response to which includes the spatial structure of the North Atlantic Oscillation (NAO). The slow, tropical ocean warming has thus forced a commensurate trend toward one extreme phase of the NAO during the past half-century.

Published

2001

20. Publisher's Note

Author

James W. Hurrell and Clara Deser

Subjects

Aquatic Science, Oceanography, Ecology, Evolution, Behavior and Systematics

Published

2010

21. Influences of the Summer North Atlantic Oscillation (SNAO) on regional climate – from the past to the future

Author

D. Fereday, Chris K. Folland, Hans W. Linderholm, Sarah Ineson, James W. Hurrell, and Jeff Knight

Subjects

Gulf Stream, Formalism (philosophy of mathematics), geography, Atlantic Equatorial mode, Oceanography, geography.geographical_feature_category, North Atlantic oscillation, Climatology, Atlantic multidecadal oscillation, Climate change, Arctic ice pack, The arctic

Abstract

Climate change – a challenge for the arctic indigenous peoples – the Inuit response Aqqaluk Lynge Total Cross Sections at High Energies — An Update Fazal-e-Aleem, Sohail Afzal Tahir, M. Alam Saeed et al. On Theory of the Statistical Generating Functional for the Order Parameter(I) — General Formalism Zhou Guang-zhao, Su Zhao-bin, Hao Bai-lin et al. Influence of Arctic sea ice on European summer precipitation J A Screen 'Physical minimum' — what problems of physics and astrophysics seem now to be especially important and interesting at the begining of the XXI century? Vitalii L Ginzburg Neoclassical light – An assessment of the voyage into Hilbert space H Jeff Kimble Wind – the challenge (from a European perspective) Erik Lundtang Petersen Influences of the Summer North Atlantic Oscillation (SNAO) on regional climate – from the past to the future

Published

2009