Your search keyword '"Mathew Barlow"' showing total 19 results

1. Advances in understanding large‐scale responses of the water cycle to climate change

Author

Daniel Rosenfeld, Laura Wilcox, Hervé Douville, Angeline G. Pendergrass, Michael P. Byrne, Thian Yew Gan, Olga Zolina, Richard P. Allan, Mathew Barlow, Annalisa Cherchi, Hayley J. Fowler, and Abigail L. S. Swann

Subjects

010504 meteorology & atmospheric sciences, Atmospheric circulation, Climate Change, Rain, General Neuroscience, Temperature, Climate change, Forcing (mathematics), Radiative forcing, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Floods, General Biochemistry, Genetics and Molecular Biology, Aerosol, Water Cycle, History and Philosophy of Science, Greenhouse gas, Humans, Environmental science, Precipitation, Water cycle, 0105 earth and related environmental sciences

Abstract

Globally, thermodynamics explains an increase in atmospheric water vapor with warming of around 7%/°C near to the surface. In contrast, global precipitation and evaporation are constrained by the Earth's energy balance to increase at ∼2-3%/°C. However, this rate of increase is suppressed by rapid atmospheric adjustments in response to greenhouse gases and absorbing aerosols that directly alter the atmospheric energy budget. Rapid adjustments to forcings, cooling effects from scattering aerosol, and observational uncertainty can explain why observed global precipitation responses are currently difficult to detect but are expected to emerge and accelerate as warming increases and aerosol forcing diminishes. Precipitation increases with warming are expected to be smaller over land than ocean due to limitations on moisture convergence, exacerbated by feedbacks and affected by rapid adjustments. Thermodynamic increases in atmospheric moisture fluxes amplify wet and dry events, driving an intensification of precipitation extremes. The rate of intensification can deviate from a simple thermodynamic response due to in-storm and larger-scale feedback processes, while changes in large-scale dynamics and catchment characteristics further modulate the frequency of flooding in response to precipitation increases. Changes in atmospheric circulation in response to radiative forcing and evolving surface temperature patterns are capable of dominating water cycle changes in some regions. Moreover, the direct impact of human activities on the water cycle through water abstraction, irrigation, and land use change is already a significant component of regional water cycle change and is expected to further increase in importance as water demand grows with global population.

Published

2020

2. North American extreme precipitation events and related large-scale meteorological patterns: a review of statistical methods, dynamics, modeling, and trends

Author

Mathew Barlow, William J. Gutowski, John R. Gyakum, Richard W. Katz, Young-Kwon Lim, Russ S. Schumacher, Michael F. Wehner, Laurie Agel, Michael Bosilovich, Allison Collow, Alexander Gershunov, Richard Grotjahn, Ruby Leung, Shawn Milrad, and Seung-Ki Min

Subjects

Climate Action, Atmospheric Science, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Meteorology & Atmospheric Sciences, 02 engineering and technology, Oceanography, 01 natural sciences, Physical Geography and Environmental Geoscience, Atmospheric Sciences, 020801 environmental engineering, 0105 earth and related environmental sciences

Abstract

This paper surveys the current state of knowledge regarding large-scale meteorological patterns (LSMPs) associated with short-duration (less than 1 week) extreme precipitation events over North America. In contrast to teleconnections, which are typically defined based on the characteristic spatial variations of a meteorological field or on the remote circulation response to a known forcing, LSMPs are defined relative to the occurrence of a specific phenomenon—here, extreme precipitation—and with an emphasis on the synoptic scales that have a primary influence in individual events, have medium-range weather predictability, and are well-resolved in both weather and climate models. For the LSMP relationship with extreme precipitation, we consider the previous literature with respect to definitions and data, dynamical mechanisms, model representation, and climate change trends. There is considerable uncertainty in identifying extremes based on existing observational precipitation data and some limitations in analyzing the associated LSMPs in reanalysis data. Many different definitions of “extreme” are in use, making it difficult to directly compare different studies. Dynamically, several types of meteorological systems—extratropical cyclones, tropical cyclones, mesoscale convective systems, and mesohighs—and several mechanisms—fronts, atmospheric rivers, and orographic ascent—have been shown to be important aspects of extreme precipitation LSMPs. The extreme precipitation is often realized through mesoscale processes organized, enhanced, or triggered by the LSMP. Understanding of model representation, trends, and projections for LSMPs is at an early stage, although some promising analysis techniques have been identified and the LSMP perspective is useful for evaluating the model dynamics associated with extremes.

Published

2019

3. More-persistent weak stratospheric polar vortex States linked to cold extremes

Author

Laurie Agel, Dim Coumou, Mathew Barlow, Ju DAh Cohen, Marlene Kretschmer, Eli Tziperman, and Water and Climate Risk

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Institut für Physik und Astronomie, Sudden stratospheric warming, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Latitude, Vortex, Polar vortex, Climatology, Middle latitudes, Extratropical cyclone, Polar amplification, SDG 13 - Climate Action, ddc:530, SDG 14 - Life Below Water, Stratosphere, Geology, 0105 earth and related environmental sciences

Abstract

The extratropical stratosphere in boreal winter is characterized by a strong circumpolar westerly jet, confining the coldest temperatures at high latitudes. The jet, referred to as the stratospheric polar vortex, is predominantly zonal and centered around the pole; however, it does exhibit large variability in wind speed and location. Previous studies showed that a weak stratospheric polar vortex can lead to cold-air outbreaks in the midlatitudes, but the exact relationships and mechanisms are unclear. Particularly, it is unclear whether stratospheric variability has contributed to the observed anomalous cooling trends in midlatitude Eurasia. Using hierarchical clustering, we show that over the last 37 years, the frequency of weak vortex states in mid- to late winter (January and February) has increased, which was accompanied by subsequent cold extremes in midlatitude Eurasia. For this region, 60% of the observed cooling in the era of Arctic amplification, that is, since 1990, can be explained by the increased frequency of weak stratospheric polar vortex states, a number that increases to almost 80% when El Niño–Southern Oscillation (ENSO) variability is included as well.

Published

2018

4. Identification of large-scale meteorological patterns associated with extreme precipitation in the US northeast

Author

Steven B. Feldstein, William J. Gutowski, Laurie Agel, and Mathew Barlow

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Context (language use), 02 engineering and technology, Atmospheric sciences, 01 natural sciences, 020801 environmental engineering, Ridge, Potential vorticity, Climatology, Environmental science, Precipitation, Tropopause, Scale (map), Trough (meteorology), 0105 earth and related environmental sciences

Abstract

Patterns of daily large-scale circulation associated with Northeast US extreme precipitation are identified using both k-means clustering (KMC) and Self-Organizing Maps (SOM) applied to tropopause height. The tropopause height provides a compact representation of the upper-tropospheric potential vorticity, which is closely related to the overall evolution and intensity of weather systems. Extreme precipitation is defined as the top 1% of daily wet-day observations at 35 Northeast stations, 1979–2008. KMC is applied on extreme precipitation days only, while the SOM algorithm is applied to all days in order to place the extreme results into the overall context of patterns for all days. Six tropopause patterns are identified through KMC for extreme day precipitation: a summertime tropopause ridge, a summertime shallow trough/ridge, a summertime shallow eastern US trough, a deeper wintertime eastern US trough, and two versions of a deep cold-weather trough located across the east-central US. Thirty SOM patterns for all days are identified. Results for all days show that 6 SOM patterns account for almost half of the extreme days, although extreme precipitation occurs in all SOM patterns. The same SOM patterns associated with extreme precipitation also routinely produce non-extreme precipitation; however, on extreme precipitation days the troughs, on average, are deeper and the downstream ridges more pronounced. Analysis of other fields associated with the large-scale patterns show various degrees of anomalously strong moisture transport preceding, and upward motion during, extreme precipitation events.

Published

2017

5. Climatology of Daily Precipitation and Extreme Precipitation Events in the Northeast United States

Author

Timothy Eichler, Jian-Hua Qian, Mathew Barlow, Laurie Agel, Frank P. Colby, and Ellen M. Douglas

Subjects

Atmospheric Science, Climatology, Precipitation types, Period (geology), Tropics, Environmental science, Storm, Precipitation, Warm season, Atmospheric sciences, Spatial distribution, Seasonal cycle

Abstract

This study examines U.S. Northeast daily precipitation and extreme precipitation characteristics for the 1979–2008 period, focusing on daily station data. Seasonal and spatial distribution, time scale, and relation to large-scale factors are examined. Both parametric and nonparametric extreme definitions are considered, and the top 1% of wet days is chosen as a balance between sample size and emphasis on tail distribution. The seasonal cycle of daily precipitation exhibits two distinct subregions: inland stations characterized by frequent precipitation that peaks in summer and coastal stations characterized by less frequent but more intense precipitation that peaks in late spring as well as early fall. For both subregions, the frequency of extreme precipitation is greatest in the warm season, while the intensity of extreme precipitation shows no distinct seasonal cycle. The majority of Northeast precipitation occurs as isolated 1-day events, while most extreme precipitation occurs on a single day embedded in 2–5-day precipitation events. On these extreme days, examination of hourly data shows that 3 h or less account for approximately 50% of daily accumulation. Northeast station precipitation extremes are not particularly spatially cohesive: over 50% of extreme events occur at single stations only, and 90% occur at only 1–3 stations concurrently. The majority of extreme days (75%–100%) are related to extratropical storms, except during September, when more than 50% of extremes are related to tropical storms. Storm tracks on extreme days are farther southwest and more clustered than for all storm-related precipitation days.

Published

2015

6. Recent Arctic amplification and extreme mid-latitude weather

Author

Judah Cohen, David Whittleston, Mathew Barlow, Klaus Dethloff, Jennifer A. Francis, Justin Jones, Dim Coumou, James E. Overland, James A. Screen, Dara Entekhabi, and Jason C. Furtado

Subjects

Arctic sea ice decline, geography, geography.geographical_feature_category, Climate change, Atmospheric sciences, Arctic ice pack, Arctic geoengineering, Extreme weather, Arctic, 13. Climate action, Effects of global warming, Climatology, SDG 13 - Climate Action, Polar amplification, General Earth and Planetary Sciences, Environmental science, SDG 14 - Life Below Water

Abstract

The Arctic region has warmed more than twice as fast as the global average-a phenomenon known as Arctic amplification. The rapid Arctic warming has contributed to dramatic melting of Arctic sea ice and spring snow cover, at a pace greater than that simulated by climate models. These profound changes to the Arctic system have coincided with a period of ostensibly more frequent extreme weather events across the Northern Hemisphere mid-latitudes, including severe winters. The possibility of a link between Arctic change and mid-latitude weather has spurred research activities that reveal three potential dynamical pathways linking Arctic amplification to mid-latitude weather: changes in storm tracks, the jet stream, and planetary waves and their associated energy propagation. Through changes in these key atmospheric features, it is possible, in principle, for sea ice and snow cover to jointly influence mid-latitude weather. However, because of incomplete knowledge of how high-latitude climate change influences these phenomena, combined with sparse and short data records, and imperfect models, large uncertainties regarding the magnitude of such an influence remain. We conclude that improved process understanding, sustained and additional Arctic observations, and better coordinated modelling studies will be needed to advance our understanding of the influences on mid-latitude weather and extreme events.

Published

2014

7. Linking Siberian Snow Cover to Precursors of Stratospheric Variability

Author

Dara Entekhabi, Judah Cohen, Justin Jones, Jason C. Furtado, David Whittleston, and Mathew Barlow

Subjects

Troposphere, Atmospheric Science, Heat flux, Arctic oscillation, Climatology, Snow line, Environmental science, Flux, Forcing (mathematics), Atmospheric sciences, Snow, Stratosphere

Abstract

Previous research has linked wintertime Arctic Oscillation (AO) variability to indices of Siberian snow cover and upward wave activity flux in the preceding fall season. Here, daily data are used to examine the surface and tropospheric processes that occur as the link between snow cover and upward forcing into the stratosphere develops. October Eurasian mean snow cover is found to be significantly related to sea level pressure (SLP) and to lower-stratosphere (100 hPa) meridional heat flux. Analysis of daily SLP and 100-hPa heat flux shows that in years with high October snow, the SLP is significantly higher from approximately 1 November to 15 December, and the 100-hPa heat flux is significantly increased with a two-week lag, from approximately 15 November to 31 December. During November–December, there are periods with upward wave activity flux extending coherently from the surface to the stratosphere, and these events occur nearly twice as often in high snow years compared to low snow years. The vertical structure of these events is a westward-tilting pattern of high eddy heights, with the largest normalized anomalies near the surface in the same region as the snow and SLP changes. These results suggest that high SLP develops in response to the snow cover and this higher pressure, in turn, provides part of the structure of a surface-to-stratosphere wave activity flux event, thus making full events more likely. Implications for improved winter forecasts exist through recognition of these precursor signals.

Published

2014

8. Disruptions of El Niño-Southern Oscillation Teleconnections by the Madden-Julian Oscillation

Author

Mathew Barlow, Andrew Hoell, Mathew Wheeler, and Chris Funk

Subjects

Geophysics, El Niño Southern Oscillation, Climatology, Observational analysis, General Earth and Planetary Sciences, Multivariate ENSO index, Environmental science, Madden–Julian oscillation, Tropical rainfall, Precipitation, Predictability, Atmospheric sciences, Teleconnection

Abstract

The El Nino–Southern Oscillation (ENSO) is the leading mode of interannual variability, with global impacts on weather and climate that have seasonal predictability. Research on the link between interannual ENSO variability and the leading mode of intraseasonal variability, the Madden–Julian oscillation (MJO), has focused mainly on the role of MJO initiating or terminating ENSO. We use observational analysis and modeling to show that the MJO has an important simultaneous link to ENSO: strong MJO activity significantly weakens the atmospheric branch of ENSO. For weak MJO conditions relative to strong MJO conditions, the average magnitude of ENSO-associated tropical precipitation anomalies increases by 63%, and the strength of hemispheric teleconnections increases by 58%. Since the MJO has predictability beyond three weeks, the relationships shown here suggest that there may be subseasonal predictability of the ENSO teleconnections to continental circulation and precipitation.

Published

2014

9. Intraseasonal and Seasonal-to-Interannual Indian Ocean Convection and Hemispheric Teleconnections

Author

Andrew Hoell, Roop Saini, and Mathew Barlow

Subjects

Convection, Atmospheric Science, Climatology, Barotropic fluid, Northern Hemisphere, Rossby wave, Outgoing longwave radiation, Madden–Julian oscillation, Precipitation, Atmospheric sciences, Geology, Teleconnection

Abstract

Deep tropical convection over the Indian Ocean leads to intense diabatic heating, a main driver of the climate system. The Northern Hemisphere circulation and precipitation associated with intraseasonal and seasonal-to-interannual components of the leading pattern of Indian Ocean convection are investigated for November–April 1979–2008. The leading pattern of Indian Ocean convection is separated into intraseasonal and seasonal-to-interannual components by filtering an index of outgoing longwave radiation at 33–105 days and greater than 105 days, yielding Madden–Julian oscillation (MJO)- and El Niño–Southern Oscillation (ENSO)-influenced patterns, respectively. Observations and barotropic Rossby wave ray tracing experiments suggest that Indian Ocean convection can influence the ENSO-related hemispheric teleconnection pattern in addition to the regional Asian teleconnection. Equivalent barotropic circulation anomalies throughout the Northern Hemisphere subtropics are associated with both seasonal-to-interannual Indian Ocean convection and ENSO. The hemispheric teleconnection associated with seasonal-to-interannual Indian Ocean convection is investigated with ray tracing, which suggests that forcing over the Indian Ocean can propagate eastward across the hemisphere and back to Asia. The relationship between the seasonal-to-interannual component of Indian Ocean convection and ENSO is investigated in terms of a gradient in sea surface temperatures (SST) over the equatorial western Pacific Ocean. When the western Pacific SST gradient is strong during ENSO, strong Maritime Continent precipitation extends further westward into the Indian Ocean, which is accompanied by enhanced tropospheric Asian circulation, similar to the seasonal-to-interannual component of Indian Ocean convection. Analysis of the three strongest interannual convection seasons shows that the strong Indian Ocean pattern of ENSO can dominate individual seasons.

Published

2013

10. Global Meteorological Drought: A Synthesis of Current Understanding with a Focus on SST Drivers of Precipitation Deficits

Author

Ernesto Hugo Berbery, Martin P. Hoerling, Lixia Zhang, Krishna Kumar Kanikicharla, Tianjun Zhou, Siegfried D. Schubert, Hailan Wang, Randal D. Koster, Mathew Barlow, Omar V. Müller, Belén Rodríguez-Fonseca, Wenju Cai, Annarita Mariotti, Carlos R. Mechoso, Ronald E. Stewart, Bradfield Lyon, Richard Seager, and Sonia I. Seneviratne

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Sea surface temperature, Climate change, 02 engineering and technology, Precipitation, Decadal variability, Atmospheric sciences, 01 natural sciences, Atmosphere, Interannual variability, East Asia, Predictability, Variability, Climate variability, 0105 earth and related environmental sciences, Atm/Ocean Structure/ Phenomena, Drought, Ephemeral key, 020801 environmental engineering, Current (stream), Climatology, Environmental science

Abstract

Drought affects virtually every region of the world, and potential shifts in its character in a changing climate are a major concern. This article presents a synthesis of current understanding of meteorological drought, with a focus on the large-scale controls on precipitation afforded by sea surface temperature (SST) anomalies, land surface feedbacks, and radiative forcings. The synthesis is primarily based on regionally focused articles submitted to the Global Drought Information System (GDIS) collection together with new results from a suite of atmospheric general circulation model experiments intended to integrate those studies into a coherent view of drought worldwide. On interannual time scales, the preeminence of ENSO as a driver of meteorological drought throughout much of the Americas, eastern Asia, Australia, and the Maritime Continent is now well established, whereas in other regions (e.g., Europe, Africa, and India), the response to ENSO is more ephemeral or nonexistent. Northern Eurasia, central Europe, and central and eastern Canada stand out as regions with few SST-forced impacts on precipitation on interannual time scales. Decadal changes in SST appear to be a major factor in the occurrence of long-term drought, as highlighted by apparent impacts on precipitation of the late 1990s “climate shifts” in the Pacific and Atlantic SST. Key remaining research challenges include (i) better quantification of unforced and forced atmospheric variability as well as land–atmosphere feedbacks, (ii) better understanding of the physical basis for the leading modes of climate variability and their predictability, and (iii) quantification of the relative contributions of internal decadal SST variability and forced climate change to long-term drought., The various contributions to this paper were made possible by the support of the host organizations of the coauthors, as noted in the acknowledgments of the contributing Global Drought Information System (GDIS) special collection papers. The GDIS effort is sponsored and supported by the World Climate Research Programme (WCRP: CLIVAR andGEWEX) and various partner organizations including the National Oceanic and Atmospheric Administration (NOAA), the National Aeronautics and Space Administration (NASA), the National Integrated Drought Information System (NIDIS), the World Meteorological Organization (WMO), the U.S. CLIVAR program, the Group on Earth Observations (GEO), the European Commission JointResearch Centre (JRC), the National Science Foundation (NSF), and the European Space Agency (ESA)–European Space Research Institute (ESRIN). Support for the overall development of this synthesis article was provided by NASA’sModeling, Analysis and Prediction Program. The GLDAS-2 data used in this study were acquired as part of the mission of NASA’s Earth Science Division and archived and distributed by the Goddard Earth Sciences (GES) Data and Information Services Center (DISC).

Published

2016

11. The Leading Pattern of Intraseasonal and Interannual Indian Ocean Precipitation Variability and Its Relationship with Asian Circulation during the Boreal Cold Season

Author

Mathew Barlow, Andrew Hoell, and Roop Saini

Subjects

Atmospheric Science, Boreal, Baroclinity, Climatology, Barotropic fluid, Outgoing longwave radiation, Environmental science, Empirical orthogonal functions, Madden–Julian oscillation, Forcing (mathematics), Precipitation, Atmospheric sciences

Abstract

The leading pattern of precipitation for the Indian Ocean, one of the most intense areas of rainfall on the globe, is calculated for November–April 1979–2008. The associated regional circulation and thermodynamic forcing of precipitation over Asia are examined at both intraseasonal and interannual time scales. The leading pattern is determined using both empirical orthogonal function analysis of monthly precipitation data and a closely related index of daily outgoing longwave radiation filtered into intraseasonal (33–105 days) and interannual (greater than 105 days) components. The leading pattern has a maximum in the tropical eastern Indian Ocean, and is closely associated with the Madden–Julian oscillation at intraseasonal time scales and related to the El Niño–Southern Oscillation at interannual time scales. Both time scales are associated with baroclinic Gill–Matsuno-like circulation responses extending over southern Asia, but the interannual component also has a strong equivalent barotropic circulation. Thermodynamically, both time scales are associated with cold temperature advection and subsidence over southwest Asia, with advection of the mean temperature by the anomalous wind more important at lower and midlevels and advection of the anomalous temperature by the mean wind more important at upper levels. For individual months, the intraseasonal variability can overwhelm the interannual variability. Enhanced Indian Ocean convection persisted for almost the entire 2007/08 season in association with severe drought over southwest Asia, but a strong intraseasonal signal in January 2008 reversed the pattern, resulting in damaging floods in the midst of drought.

Published

2012

12. Dynamics and Thermodynamics of the Regional Response to the Indian Monsoon Onset

Author

Andrew Hoell, Roop Saini, and Mathew Barlow

Subjects

Monsoon of South Asia, Atmospheric Science, Advection, Middle latitudes, Climatology, Rossby wave, Subsidence (atmosphere), Westerlies, Precipitation, Atmospheric sciences, Monsoon, Geology

Abstract

The regional influence of the Indian monsoon onset is examined though observational analysis focusing on the Rodwell–Hoskins “monsoon-desert” hypothesis, which proposes that the strong diabatic heating associated with the monsoon produces a Gill-like Rossby wave response that thermodynamically interacts with the midlatitude westerly jet to produce subsidence and reduced rainfall to the west of the monsoon. Here, the authors analyze this proposed mechanism in terms of changes to the thermodynamic energy equation, regional circulation, and precipitation between the 10-day periods before and after the monsoon onset, for all onset dates in the 1958–2000 period. A Rossby-like response to the monsoon onset is clear in the observational data and is associated with horizontal temperature advection at midlevels as the westerlies intersect the warm temperature anomalies of the Rossby wave. Analysis of the thermodynamic equation verifies that the horizontal temperature advection is indeed balanced by subsidence over areas of North Africa, the Mediterranean, and the Middle East, and there is an associated decrease in precipitation over those regions. Despite the increased subsidence, diabatic heating changes are small in these regions so diabatic enhancement does not appear to be a primary factor in the response to the onset. This analysis also shows that the same processes that favor subsidence to the west of the monsoon also force rising motion over northern India and appear to be an important factor for the inland development of the monsoon. Comparison of strong and weak onsets further validates these relationships.

Published

2011

13. Decadal Fluctuations in Planetary Wave Forcing Modulate Global Warming in Late Boreal Winter

Author

Mathew Barlow, Kazuyuki Saito, and Judah Cohen

Subjects

Atmospheric Science, Boreal, Climatology, Greenhouse gas, Global warming, Trend surface analysis, Northern Hemisphere, Climate change, Environmental science, Global change, Forcing (mathematics), Atmospheric sciences

Abstract

The warming trend in global surface temperatures over the last 40 yr is clear and consistent with anthropogenic increases in greenhouse gases. Over the last 2 decades, this trend appears to have accelerated. In contrast to this general behavior, however, here it is shown that trends during the boreal cold months in the recent period have developed a marked asymmetry between early winter and late winter for the Northern Hemisphere, with vigorous warming in October–December followed by a reversal to a neutral/cold trend in January–March. This observed asymmetry in the cold half of the boreal year is linked to a two-way stratosphere–troposphere interaction, which is strongest in the Northern Hemisphere during late winter and is related to variability in Eurasian land surface conditions during autumn. This link has been demonstrated for year-to-year variability and used to improve seasonal time-scale winter forecasts; here, this coupling is shown to strongly modulate the warming trend, with implications for decadal-scale temperature projections.

Published

2009

14. Stratosphere–Troposphere Coupling and Links with Eurasian Land Surface Variability

Author

Mathew Barlow, Paul J. Kushner, Judah Cohen, and Kazuyuki Saito

Subjects

Troposphere, Atmospheric Science, Arctic oscillation, Atmospheric circulation, Polar vortex, Climatology, Extratropical cyclone, Northern Hemisphere, Environmental science, Snow, Atmospheric sciences, Stratosphere

Abstract

A diagnostic of Northern Hemisphere winter extratropical stratosphere–troposphere interactions is presented to facilitate the study of stratosphere–troposphere coupling and to examine what might influence these interactions. The diagnostic is a multivariate EOF combining lower-stratospheric planetary wave activity flux in December with sea level pressure in January. This EOF analysis captures a strong linkage between the vertical component of lower-stratospheric wave activity over Eurasia and the subsequent development of hemisphere-wide surface circulation anomalies, which are strongly related to the Arctic Oscillation. Wintertime stratosphere–troposphere events picked out by this diagnostic often have a precursor in autumn: years with large October snow extent over Eurasia feature strong wintertime upward-propagating planetary wave pulses, a weaker wintertime polar vortex, and high geopotential heights in the wintertime polar troposphere. This provides further evidence for predictability of wintertime circulation based on autumnal snow extent over Eurasia. These results also raise the question of how the atmosphere will respond to a modified snow cover in a changing climate.

Published

2007

15. Modulation of Daily Precipitation over Southwest Asia by the Madden–Julian Oscillation

Author

Heidi Cullen, Mathew Barlow, Bradfield Lyon, and Matthew C. Wheeler

Subjects

Atmospheric Science, Indian ocean, Negative phase, Climatology, Environmental science, Outgoing longwave radiation, Storm, Madden–Julian oscillation, Precipitation, Predictability, Extreme value theory, Atmospheric sciences

Abstract

Analysis of daily observations shows that wintertime (November–April) precipitation over Southwest Asia is modulated by Madden–Julian oscillation (MJO) activity in the eastern Indian Ocean, with strength comparable to the interannual variability. Daily outgoing longwave radiation (OLR) for 1979–2001 is used to provide a long and consistent, but indirect, estimate of precipitation, and daily records from 13 stations in Afghanistan reporting at least 50% of the time for 1979–85 are used to provide direct, but shorter and irregularly reported, precipitation data. In the station data, for the average of all available stations, there is a 23% increase in daily precipitation relative to the mean when the phase of the MJO is negative (suppressed tropical convection in the eastern Indian Ocean), and a corresponding decrease when the MJO is positive. The distribution of extremes is also affected such that the 10 wettest days all occur during the negative MJO phase. The longer record of OLR data indicates that the effect of the MJO is quite consistent from year to year, with the anomalies averaged over Southwest Asia more negative (indicating more rain) for the negative phase of the MJO for each of the 22 yr in the record. Additionally, in 9 of the 22 yr the average influence of the MJO is larger than the interannual variability (e.g., the relationship results in anomalously wet periods even in dry years and vice versa). Examination of NCEP–NCAR reanalysis data shows that the MJO modifies both the local jet structure and, through changes to the thermodynamic balance, the vertical motion field over Southwest Asia, consistent with the observed modulation of the associated synoptic precipitation. A simple persistence scheme for forecasting the sign of the MJO suggests that the modulation of Southwest Asia precipitation may be predictable for 3-week periods. Finally, analysis of changes in storm evolution in Southwest Asia due to the influence of the MJO shows a large difference in strength as the storms move over Afghanistan, with apparent relevance for the flooding event of 12–13 April 2002.

Published

2005

16. The NAO, the AO, and Global Warming: How Closely Related?

Author

Mathew Barlow and Judah Cohen

Subjects

Related factors, Atmospheric Science, Arctic oscillation, North Atlantic oscillation, Climatology, Global warming, Northern Hemisphere, Environmental science, Atmospheric sciences, Regional warming, Snow cover

Abstract

The North Atlantic Oscillation (NAO) and the closely related Arctic Oscillation (AO) strongly affect Northern Hemisphere (NH) surface temperatures with patterns reported similar to the global warming trend. The NAO and AO were in a positive trend for much of the 1970s and 1980s with historic highs in the early 1990s, and it has been suggested that they contributed significantly to the global warming signal. The trends in standard indices of the AO, NAO, and NH average surface temperature for December–February, 1950–2004, and the associated patterns in surface temperature anomalies are examined. Also analyzed are factors previously identified as relating to the NAO, AO, and their positive trend: North Atlantic sea surface temperatures (SSTs), Indo–Pacific warm pool SSTs, stratospheric circulation, and Eurasian snow cover. Recently, the NAO and AO indices have been decreasing; when these data are included, the overall trends for the past 30 years are weak to nonexistent and are strongly dependent on the choice of start and end date. In clear distinction, the wintertime hemispheric warming trend has been vigorous and consistent throughout the entire period. When considered for the whole hemisphere, the NAO/AO patterns can also be distinguished from the trend pattern. Thus the December–February warming trend may be distinguished from the AO and NAO in terms of the strength, consistency, and pattern of the trend. These results are insensitive to choice of index or dataset. While the NAO and AO may contribute to hemispheric and regional warming for multiyear periods, these differences suggest that the large-scale features of the global warming trend over the last 30 years are unrelated to the AO and NAO. The related factors may also be clearly distinguished, with warm pool SSTs linked to the warming trend, while the others are linked to the NAO and AO.

Published

2005

17. Asymmetric seasonal temperature trends

Author

Vladimir A. Alexeev, J. E. Cherry, Jason C. Furtado, Judah Cohen, and Mathew Barlow

Subjects

Maximum temperature, Geophysics, Boreal, Global temperature, Climatology, Global warming, Northern Hemisphere, General Earth and Planetary Sciences, Environmental science, Climate change, Forcing (mathematics), Atmospheric sciences, Latitude

Abstract

[1] Current consensus on global climate change predicts warming trends driven by anthropogenic forcing, with maximum temperature changes projected in the Northern Hemisphere (NH) high latitudes during winter. Yet, global temperature trends show little warming over the most recent decade or so. For longer time periods appropriate to the assessment of trends, however, global temperatures have experienced significant warming trends for all seasons except winter, when cooling trends exist instead across large stretches of eastern North America and northern Eurasia. Hence, the most recent lapse in global warming is a seasonal phenomenon, prevalent only in boreal winter. Additionally, we show that the largest regional contributor to global temperature trends over the past two decades is land surface temperatures in the NH extratropics. Therefore, proposed mechanisms explaining the fluctuations in global annual temperatures should address this apparent seasonal asymmetry.

Published

2012

18. Examining the wintertime response to tropical convection over the Indian Ocean by modifying convective heating in a full atmospheric model

Author

Andrew Hoell, Mathew Barlow, and Frank P. Colby

Subjects

Convection, Geophysics, Subtropical Indian Ocean Dipole, Climatology, Middle latitudes, Rossby wave, General Earth and Planetary Sciences, Environmental science, Madden–Julian oscillation, Atmospheric model, Precipitation, Indian Ocean Dipole, Atmospheric sciences

Abstract

[1] The boreal winter response to tropical convection in the eastern Indian Ocean is investigated by increasing the mid-level diabatic heating for that region in the NCAR Community Atmosphere Model, version 3.1. The response is quite similar to the analytic Gill solution to steady heating, with a pair of Rossby wave packets poleward and to the west of the heating, extending into mid-latitudes, and a Kelvin response to the east of the heating. Changes to tropical convection in the eastern Indian Ocean are an important component of several important modes of atmospheric variability, including the Madden-Julian Oscillation, some El Nino-Southern Oscillation events, and the Indian Ocean Dipole. The simulated response has considerable similarities to observational aspects of these modes, both in terms of the Gill-like circulation patterns and changes to precipitation over Southwest Asia, demonstrating the central importance of the Indian Ocean convection in determining the regional response.

Published

2007

19. Arctic warming, increasing snow cover and widespread boreal winter cooling

Author

Vladimir A. Alexeev, Jason C. Furtado, J. E. Cherry, Judah Cohen, and Mathew Barlow

Subjects

Renewable Energy, Sustainability and the Environment, Public Health, Environmental and Occupational Health, Northern Hemisphere, Atmospheric sciences, Latitude, Boreal, Arctic, Internal variability, General Circulation Model, Climatology, Middle latitudes, Environmental science, Snow cover, General Environmental Science

Abstract

The most up to date consensus from global climate models predicts warming in the Northern Hemisphere (NH) high latitudes to middle latitudes during boreal winter. However, recent trends in observed NH winter surface temperatures diverge from these projections. For the last two decades, large-scale cooling trends have existed instead across large stretches of eastern North America and northern Eurasia. We argue that this unforeseen trend is probably not due to internal variability alone. Instead, evidence suggests that summer and autumn warming trends are concurrent with increases in high-latitude moisture and an increase in Eurasian snow cover, which dynamically induces large-scale wintertime cooling. Understanding this counterintuitive response to radiative warming of the climate system has the potential for improving climate predictions at seasonal and longer timescales.

Published

2012