Your search keyword '"Simpson, Isla"' showing total 31 results

1. Revisiting the reanalysis-model discrepancy in Southern Hemisphere winter storm track trends.

Author

Kang, Joonsuk M., Shaw, Tiffany A., Kang, Sarah M., Simpson, Isla R., and Yu, Yue

Subjects

ATMOSPHERIC models, WINTER storms, OCEAN, COOLING, SIMULATION methods & models

Abstract

Southern Hemisphere (SH) storminess has increased in the satellite era and recent work suggests comprehensive climate models significantly underestimate the trend. Here, we revisit this reanalysis-model trend discrepancy to better understand the mechanisms underlie it. A comprehensive like-for-like analysis shows reanalysis trends exhibit large uncertainty, and coupled climate model simulations exhibit weaker trends than most but not all reanalyses. However, simulations with prescribed sea surface temperature (SST) exhibit significantly greater storminess trends, particularly in the South Pacific, implying SST trend discrepancies in coupled simulations impact storminess trends. Using pacemaker simulations that correct Southern Ocean and tropical east Pacific SST trend discrepancies, we show that storminess trends in coupled simulations are underestimated because they do not capture the enhanced storminess resulting from Southern Ocean cooling and La-Nina-like teleconnection trends. Our findings emphasize large reanalysis uncertainty in SH circulation trends and the impact of regional SST trend discrepancies on circulation trends. [ABSTRACT FROM AUTHOR]

Published

2024

2. Northern Hemisphere Stratosphere‐Troposphere Circulation Change in CMIP6 Models: 2. Mechanisms and Sources of the Spread.

Author

Karpechko, Alexey Yu., Wu, Zheng, Simpson, Isla R., Kretschmer, Marlene, Afargan‐Gerstman, Hilla, Butler, Amy H., Domeisen, Daniela I.V., Garny, Hella, Lawrence, Zachary, Manzini, Elisa, and Sigmond, Michael

Subjects

POLAR vortex, CLIMATE change models, GREENHOUSE gases, ATMOSPHERIC models, ROSSBY waves, STANDING waves

Abstract

We analyze the sources for spread in the response of the Northern Hemisphere wintertime stratospheric polar vortex (SPV) to global warming in Climate Model Intercomparison Project Phase 5 (CMIP5) and Phase 6 (CMIP6) model projections. About half of the intermodel spread in SPV projections by CMIP6 models, but less than a third in CMIP5 models, can be attributed to the intermodel spread in stationary planetary wave driving. In CMIP6, SPV weakening is mostly driven by increased upward wave flux from the troposphere, while SPV strengthening is associated with increased equatorward wave propagation away from the polar stratosphere. We test hypothesized factors contributing to changes in the upward and equatorward planetary wave fluxes and show that an across‐model regression using projected global warming rates, strengthening of the subtropical jet and basic state lower stratospheric wind biases as predictors can explain nearly the same fraction in the CMIP6 SPV spread as the planetary wave driving (r = 0.67). The dependence of the SPV spread on the model biases in the basic state winds offers a possible emergent constraint; however, a large uncertainty prevents a substantial reduction of the projected SPV spread. The lack of this dependence in CMIP5 further calls for better understanding of underlying causes. Our results improve understanding of projected SPV uncertainty; however, further narrowing of the uncertainty remains challenging. Plain Language Summary: Previous studies showed that changes in the strength of the Northern Hemisphere wintertime stratospheric polar vortex can affect near‐surface weather on various timescales. However, climate models do not agree on whether the polar vortex will weaken or strengthen during the 21st century. Here, we use Climate Model Intercomparison Project Phase 5 (CMIP5) and Phase 6 (CMIP6) experiments to better understand how the polar vortex will respond to future greenhouse gas emissions. We show that changes in the propagation of large‐scale atmospheric waves can explain nearly half of the spread in the vortex strength projections by the end of the 21st century by CMIP6 models. Increased upward propagation of the waves to the stratosphere leads to vortex weakening while increased equatorward propagation within the stratosphere leads to strengthening. We identify three factors associated with projected changes in the vortex strength across CMIP6 models: projected rates of global warming, projected rates of subtropical jet stream strengthening and model errors in lower stratospheric winds in the past climate. Stronger global warming rates and stronger past lower stratospheric winds are associated with vortex strengthening, while larger strengthening of the subtropical jet stream is associated with weakening. However, these relationships are weak in CMIP5 models. Key Points: About half of the projected stratospheric polar vortex (SPV) uncertainty in Climate Model Intercomparison Project Phase 6 (CMIP6) can be attributed to stationary planetary wave drivingProjected polar vortex weakening and strengthening are linked to increased upward and equatorward wave propagation respectivelyA relationship is found between past lower stratospheric wind biases and SPV projections across CMIP6 models [ABSTRACT FROM AUTHOR]

Published

2024

3. Resolving Weather Fronts Increases the Large‐Scale Circulation Response to Gulf Stream SST Anomalies in Variable‐Resolution CESM2 Simulations.

Author

Wills, Robert C. J., Herrington, Adam R., Simpson, Isla R., and Battisti, David S.

Subjects

FRONTS (Meteorology), GULF Stream, GENERAL circulation model, ATMOSPHERIC models, NORTH Atlantic oscillation, ATMOSPHERIC circulation, OCEAN temperature

Abstract

Canonical understanding based on general circulation models (GCMs) is that the atmospheric circulation response to midlatitude sea‐surface temperature (SST) anomalies is weak compared to the larger influence of tropical SST anomalies. However, the ∼100‐km horizontal resolution of modern GCMs is too coarse to resolve strong updrafts within weather fronts, which could provide a pathway for surface anomalies to be communicated aloft. Here, we investigate the large‐scale atmospheric circulation response to idealized Gulf Stream SST anomalies in Community Atmosphere Model (CAM6) simulations with 14‐km regional grid refinement over the North Atlantic, and compare it to the responses in simulations with 28‐km regional refinement and uniform 111‐km resolution. The highest resolution simulations show a large positive response of the wintertime North Atlantic Oscillation (NAO) to positive SST anomalies in the Gulf Stream, a 0.4‐standard‐deviation anomaly in the seasonal‐mean NAO for 2°C SST anomalies. The lower‐resolution simulations show a weaker response with a different spatial structure. The enhanced large‐scale circulation response results from an increase in resolved vertical motions with resolution and an associated increase in the influence of SST anomalies on transient‐eddy heat and momentum fluxes in the free troposphere. In response to positive SST anomalies, these processes lead to a stronger and less variable North Atlantic jet, as is characteristic of positive NAO anomalies. Our results suggest that the atmosphere responds differently to midlatitude SST anomalies in higher‐resolution models and that regional refinement in key regions offers a potential pathway to improve multi‐year regional climate predictions based on midlatitude SSTs. Plain Language Summary: Variations in the ocean surface temperature (SST) influence the atmospheric circulation and thus climate over land. Canonical understanding is that tropical SSTs are more important than SSTs in midlatitudes. However, this understanding is based on climate models that don't resolve processes at scales less than 100 km. Here, we show that by increasing the atmospheric model resolution to resolve features on smaller scales, such as weather fronts, we find a larger atmospheric circulation response to midlatitude SST anomalies in the North Atlantic. North Atlantic SST anomalies can be predicted multiple years in advance, and a larger atmospheric circulation response to these predictable SST anomalies therefore implies increased predictability of climate over the surrounding land regions. Key Points: There is a large circulation response to idealized Gulf Stream sea‐surface temperature (SST) anomalies in an atmospheric model with 14‐km regional grid refinementThis response is weaker or absent in simulations with 28‐km or coarser resolution, which do not fully resolve mesoscale frontal processesTransient‐eddy fluxes of heat and momentum are modified as fronts pass over warm SSTs, leading to a large‐scale circulation response [ABSTRACT FROM AUTHOR]

Published

2024

4. Observed humidity trends in dry regions contradict climate models.

Author

Simpson, Isla R., McKinnon, Karen A., Kennedy, Daniel, Lawrence, David M., Lehner, Flavio, and Seager, Richard

Subjects

*ATMOSPHERIC water vapor, *ATMOSPHERIC models, *HUMIDITY, *ARID regions, *MOISTURE

Abstract

Arid and semi-arid regions of the world are particularly vulnerable to greenhouse gas-driven hydroclimate change. Climate models are our primary tool for projecting the future hydroclimate that society in these regions must adapt to, but here, we present a concerning discrepancy between observed and model-based historical hydroclimate trends. Over the arid/semi-arid regions of the world, the predominant signal in all model simulations is an increase in atmospheric water vapor, on average, over the last four decades, in association with the increased water vapor-holding capacity of a warmer atmosphere. In observations, this increase in atmospheric water vapor has not happened, suggesting that the availability of moisture to satisfy the increased atmospheric demand is lower in reality than in models in arid/semi-arid regions. This discrepancy is most clear in locations that are arid/semi-arid year round, but it is also apparent in more humid regions during the most arid months of the year. It indicates a major gap in our understanding and modeling capabilities which could have severe implications for hydroclimate projections, including fire hazard, moving forward. [ABSTRACT FROM AUTHOR]

Published

2024

5. Origins of Uncertainty in the Response of the Summer North Pacific Subtropical High to CO2 Forcing.

Author

Lu, Kezhou, He, Jie, and Simpson, Isla R.

Subjects

LAND surface temperature, TYPHOONS, OCEAN temperature, ATMOSPHERIC models, SUMMER, THEORY of wave motion

Abstract

The variability of the summer North Pacific Subtropical High (NPSH) has substantial socioeconomic impacts. However, state‐of‐the‐art climate models significantly disagree on the response of the NPSH to anthropogenic warming. Inter‐model spread in NPSH projections originates from models' inconsistency in simulating tropical precipitation changes. This inconsistency in precipitation changes is partly due to inter‐model spread in tropical sea surface temperature (SST) changes, but it can also occur independently of uncertainty in SST changes. Here, we show that both types of precipitation uncertainty influence the NPSH via the Matsuno‐Gill wave response, but their relative impact varies by region. Through the modulation of low cloud fraction, inter‐model spread of the NPSH can have a further impact on extra‐tropical land surface temperature. The teleconnection between tropical precipitation and the NPSH is examined through a series of numerical experiments. Plain Language Summary: The North Pacific Subtropical High (NPSH) is a semi‐permanent high‐pressure system located in the subtropical North Pacific. The variability in the summer NPSH has a significant impact on the monsoon and typhoons over East Asia and the hydroclimate of California. However, future projections of the NPSH using state‐of‐the‐art climate models remain highly uncertain. By evaluating how much individual models deviate from the multi‐model mean at different locations, we find four hot spots of high uncertainty in NPSH projections. Our analysis further reveals that the primary source of model variance in changes in the NPSH is tropical precipitation, which can be attributed to both inter‐model SST‐driven and non‐inter‐model SST‐driven factors. Through numerical experiments, we demonstrate that the teleconnection between tropical precipitation and the NPSH is achieved through wave propagation. Key Points: Model spread in the response of the summer North Pacific Subtropical High (NPSH) to CO2 stems from model spread in simulating tropical processesModel spread in tropical sea surface temperature (SST) changes modulates the NPSH by influencing tropical precipitationModel spread in tropical precipitation changes independent of model spread in SST changes also adds to the uncertainty of the NPSH response [ABSTRACT FROM AUTHOR]

Published

2023

6. The Lack of a QBO‐MJO Connection in Climate Models With a Nudged Stratosphere.

Author

Martin, Zane K., Simpson, Isla R., Lin, Pu, Orbe, Clara, Tang, Qi, Caron, Julie M., Chen, Chih‐Chieh, Kim, Hyemi, Leung, L. Ruby, Richter, Jadwiga H., and Xie, Shaocheng

Subjects

ATMOSPHERIC models, MADDEN-Julian oscillation, STRATOSPHERE, ZONAL winds, QUASI-biennial oscillation (Meteorology), WESTERLIES

Abstract

The observed stratospheric quasi‐biennial oscillation (QBO) and the tropospheric Madden‐Julian oscillation (MJO) are strongly connected in boreal winter, with stronger MJO activity when lower‐stratospheric winds are easterly. However, the current generation of climate models with internally generated representations of the QBO and MJO do not simulate the observed QBO‐MJO connection, for reasons that remain unclear. This study builds on prior work exploring the QBO‐MJO link in climate models whose stratospheric winds are relaxed toward reanalysis, reducing stratospheric biases in the model and imposing a realistic QBO. A series of ensemble experiments are performed using four state‐of‐the‐art climate models capable of representing the MJO over the period 1980–2015, each with similar nudging in the stratosphere. In these four models, nudging leads to a good representation of QBO wind and temperature signals, however no model simulates the observed QBO‐MJO relationship. Biases in MJO vertical structure and cloud‐radiative feedbacks are investigated, but no conclusive model bias or mechanism is identified that explains the lack of a QBO‐MJO connection. Plain Language Summary: Observations show a strong link between the stratospheric quasi‐biennial oscillation (QBO)—the alternation of tropical stratospheric zonal winds between easterly and westerly phases—and the Madden‐Julian oscillation (MJO), an eastward propagating phenomenon in the tropical troposphere in which the circulation and convection are coupled. Stronger MJO activity is observed when lower‐stratospheric winds are easterly. This coupling is intriguing for many reasons, but most practically because it suggests that the stratosphere can potentially enhance surface weather and inform subseasonal climate prediction. However, current climate models do not show this observed connection. One reason may be related to biases in how models simulate stratospheric winds, which can be corrected for in an artificial way by relaxing the model simulated winds to better match observationally constrained data sets. One recent study, however, showed that correcting for this bias using this approach in one climate model still fails to produce credible QBO‐MJO coupling. Here we expand that analysis to include four climate models and find that no model produces a robust QBO‐MJO relationship like that seen in observations. Our results show that properly representing the QBO winds and temperatures via nudging is therefore not sufficient for reproducing the observed relationship. Furthermore, while biases in how models represent cloud processes may still be a likely culprit, any definitive model bias or missing mechanism remains elusive. Key Points: The link between the quasi‐biennial oscillation (QBO) and Madden‐Julian oscillation (MJO) is explored in four climate models with nudged stratospheric winds and free‐evolving tropospheresNo model shows as strong of a QBO‐MJO connection as in observationsModel biases in cloud‐radiative feedbacks and MJO vertical velocity are diagnosed, but neither conclusively explains the lack of a QBO‐MJO connection [ABSTRACT FROM AUTHOR]

Published

2023

7. Dynamical and Thermodynamical Causes of Large-Scale Changes in the Hydrological Cycle over North America in Response to Global Warming

Author

Seager, Richard, Neelin, David, Simpson, Isla, Liu, Haibo, Henderson, Naomi, Shaw, Tiffany, Kushnir, Yochanan, Ting, Mingfang, and Cook, Benjamin

Published

2014

8. Reduced Southern Ocean warming enhances global skill and signal-to-noise in an eddy-resolving decadal prediction system.

Author

Yeager, Stephen G., Chang, Ping, Danabasoglu, Gokhan, Rosenbloom, Nan, Zhang, Qiuying, Castruccio, Fred S., Gopal, Abishek, Cameron Rencurrel, M., and Simpson, Isla R.

Subjects

GLOBAL warming, OCEAN, FORECASTING, ATMOSPHERIC models, COMMUNITIES

Abstract

The impact of increased model horizontal resolution on climate prediction performance is examined by comparing results from low-resolution (LR) and high-resolution (HR) decadal prediction simulations conducted with the Community Earth System Model (CESM). There is general improvement in global skill and signal-to-noise characteristics, with particularly noteworthy improvements in the eastern tropical Pacific, when resolution is increased from order 1° in all components to order 0.1°/0.25° in the ocean/atmosphere. A key advance in the ocean eddy-resolving HR system is the reduction of unrealistic warming in the Southern Ocean (SO) which we hypothesize has global ramifications through its impacts on tropical Pacific multidecadal variability. The results suggest that accurate representation of SO processes is critical for improving decadal climate predictions globally and for addressing longstanding issues with coupled climate model simulations of recent Earth system change. [ABSTRACT FROM AUTHOR]

Published

2023

9. Southern Annular Mode Dynamics in Observations and Models. Part I : The Influence of Climatological Zonal Wind Biases in a Comprehensive GCM

Author

Simpson, Isla R., Hitchcock, Peter, Shepherd, Theodore G., and Scinocca, John F.

Published

2013

10. Mechanisms behind the Springtime North Pacific ENSO Teleconnection Bias in Climate Models.

Author

Chen, Ruyan, Simpson, Isla R., Deser, Clara, Wang, Bin, and Du, Yan

Subjects

*ATMOSPHERIC models, *SPRING, *TROPICAL cyclones, *SOUTHERN oscillation, *STANDING waves, EL Nino, LA Nina

Abstract

Previous studies have shown that models overestimate the strength of ENSO teleconnections to the North Pacific during springtime, but the underlying reasons for this bias remain unknown. In this work, the relative contributions from basic-state and thermodynamic/dynamic forcing factors are disentangled through idealized experiments with the Community Earth System Model and a range of stationary wave modeling experiments. It is revealed that in CESM1 the diabatic heating biases over the tropical Indian Ocean and tropical central-western Pacific jointly favor a cyclonic (anticyclonic) circulation bias to occur in the North Pacific during the springtime of El Niño (La Niña) events. On one hand, the difference in the modeled and observed climatological basic state does not lead to the bias formation directly, as the diabatic heating biases are the primary cause. On the other hand, the springtime basic state is conducive to a more vigorous stationary wave response to the biased diabatic heating than the wintertime state, and this explains why the teleconnection bias occurs during springtime but not in winter. An iterative bias-correction approach is then implemented in the atmospheric model component of CESM1 to verify the linkage between the tropical diabatic heating bias and the teleconnection bias. Moreover, this explanation is shown to be relevant in other models of phase 5 of the Coupled Model Intercomparison Project (CMIP5) as a strong relationship is found between biases in ENSO-related tropical central-western Pacific/Indian Ocean precipitation and North Pacific circulation across models in spring. Significance Statement: The purpose of this study is to explain why climate models tend to overestimate the springtime ENSO teleconnection to the North Pacific. Through both simplified and comprehensive model experiments, we found that the diabatic heating biases over the tropical Indian Ocean and central-western Pacific basins are the main cause behind the circulation bias. Although similar heating biases also occur in winter, the spring mean climate state is more sensitive to the biased heating than the winter mean state. These findings are useful for developing future climate models that would better simulate the springtime climate response during the ENSO events, as the same problem can be found in many other models. [ABSTRACT FROM AUTHOR]

Published

2022

11. Mechanisms of a Meteorological Drought Onset: Summer 2020 to Spring 2021 in Southwestern North America.

Author

Seager, Richard, Ting, Mingfang, Alexander, Patrick, Nakamura, Jennifer, Liu, Haibo, Li, Cuihua, and Simpson, Isla R.

Subjects

SPRING, DROUGHTS, ATMOSPHERIC models, LA Nina, SUMMER, CLIMATE change

Abstract

By summer 2021 moderate to exceptional drought impacted 28% of North America, focused west of the Mississippi, with serious impacts on fire, water resources, and agriculture. Here, using reanalyses and SST-forced climate models, we examine the onset and development of this southwestern drought from its inception in summer 2020 through winter and spring 2020/21. The drought severity in summer 2021 resulted from four consecutive prior seasons in which precipitation in the southwest United States was the lowest on record or, at least, extremely dry. The dry conditions in summer 2020 arose from internal atmospheric variability but are beyond the range of what the studied atmosphere models simulate for that season. From winter 2020 through spring 2021 the worsening drought conditions were guided by the development of a La Niña in the tropical Pacific Ocean. Decadal variability in the Pacific Ocean aided drought in the southern part of the region by driving the cool season to be drier during the last two decades. There is also evidence that the southern part of the region in spring is drying due to human-driven climate change. In sum the drought onset was driven by a combination of internal atmospheric variability and interannual climate variability and aided by natural decadal variability and human-driven climate change. [ABSTRACT FROM AUTHOR]

Published

2022

12. How Unexpected Was the 2021 Pacific Northwest Heatwave?

Author

McKinnon, Karen A. and Simpson, Isla R.

Subjects

*HEAT waves (Meteorology), *ATMOSPHERIC models, *HIGH temperatures, *CLIMATE change, *COMMUNITIES

Abstract

The 2021 Pacific Northwest heatwave featured record‐smashing high temperatures, raising questions about whether extremes are changing faster than the mean, and challenging our ability to estimate the probability of the event. Here, we identify and draw on the strong relationship between the climatological higher‐order statistics of temperature (skewness and kurtosis) and the magnitude of extreme events to quantify the likelihood of comparable events using a large climate model ensemble (Community Earth System Model version 2 Large Ensemble [CESM2‐LE]). In general, CESM2 can simulate temperature anomalies as extreme as those observed in 2021, but they are rare: temperature anomalies that exceed 4.5σ occur with an approximate frequency of one in a hundred thousand years. The historical data does not indicate that the upper tail of temperature is warming faster than the mean; however, future projections for locations with similar climatological moments to the Pacific Northwest do show significant positive trends in the probability of the most extreme events. Plain Language Summary: While the 2021 Pacific Northwest heatwave was reasonably well‐forecasted by weather models, it was unexpected by many in the climate community because the high temperatures were so extreme. The event has raised questions about whether the probability of very extreme events is increasing faster than would be expected based on historical warming of average temperatures. Here, we analyze the spread of temperatures around the average, which has increased by 1.5°C since 1960, to provide a rough estimate of the probability of the very extreme event of 2021, and assess whether the probability of extreme heat is changing beyond what is expected from warming of average temperatures. By drawing on climate model simulations from regions that are analogous to the Pacific Northwest, we find that similar events can be simulated by climate models, but that they are very rare: when they occur, they are often the largest event across nearly 10,000 years of data. The climate model also suggests that the most extreme events may increase in probability in the future beyond what would be expected from the average climate change signal, although we do not yet see clear evidence of this in the observations. Key Points: Summer temperatures in the Pacific Northwest are positively skewed, so hot extremes are more likely than if the distributions were normalCommunity Earth System Model version 2 (CESM2) can simulate events as extreme as the 2021 Pacific Northwest heatwave at points with similar high‐order statistics, but they are rareObservations do not indicate that the upper tail is warming more than the mean, but CESM2 projects this behavior for very extreme events [ABSTRACT FROM AUTHOR]

Published

2022

13. Northern Hemisphere Stratosphere‐Troposphere Circulation Change in CMIP6 Models: 1. Inter‐Model Spread and Scenario Sensitivity.

Author

Karpechko, Alexey Yu., Afargan‐Gerstman, Hilla, Butler, Amy H., Domeisen, Daniela I. V., Kretschmer, Marlene, Lawrence, Zachary, Manzini, Elisa, Sigmond, Michael, Simpson, Isla R., and Wu, Zheng

Subjects

POLAR vortex, ATMOSPHERIC models, ENERGY futures, GLOBAL warming, SURFACE temperature, CLIMATE change

Abstract

Projected changes in the Northern Hemisphere stratospheric polar vortex are analyzed using Climate Model Intercomparison Project Phase 6 experiments. Previous studies showed that projections of the wintertime zonally averaged polar vortex strength diverge widely between climate models with no agreement on the sign of change, and that this uncertainty contributes to the regional climate change uncertainty. Here, we show that there remains large uncertainty in the projected strength of the polar vortex in experiments with global warming levels ranging from moderate (SSP245 runs) to large (Abrupt‐4xCO2 runs), and that the uncertainty maximizes in winter. Partitioning of the uncertainty in wintertime polar vortex strength projections reveals that, by the end of the 21st century, model uncertainty contributes half of the total uncertainty, with scenario uncertainty contributing only 10%. Regression analysis shows that up to 20% of the intermodel spread in projected precipitation over the Iberian Peninsula and northwestern US, and 20%–30% in near‐surface temperature over western US and northern Eurasian, can be associated with the spread in vortex strength projections after accounting for global warming. While changes in the magnitude and sign of the zonally averaged vortex strength are uncertain, most models (>95%) predict an eastward shift of the vortex by 8°–20° degrees in longitude relative to its historical location with the magnitude of the shift increasing for larger global warming levels. There is less agreement across models on a latitudinal shift, whose direction and magnitude correlate with changes in the zonally averaged vortex strength so that vortex weakening/strengthening corresponds to a southward/poleward shift. Plain Language Summary: Previous studies showed that changes in the strength of the winds in the Northern Hemisphere wintertime stratosphere, the so‐called polar vortex, can affect near‐surface winds and precipitation on various timescales. However, climate models do not agree on whether the polar vortex will weaken or strengthen during the 21st century. Here, we use Climate Model Intercomparison Project Phase 6 experiments to better understand how the polar vortex will respond to future greenhouse gas emissions. We show that half of the uncertainty in the vortex strength projections by the end of the 21st century is due to climate model errors (model uncertainty). We show that the uncertainty in the vortex strength projections is linked to the uncertainty in projected precipitation over the Iberian Peninsula and northwestern US and projected near‐surface temperature over the western US and northern Eurasia. Most models predict an eastward shift of the vortex relative to its historical location but we do not detect any influence of the vortex longitudinal shift on surface precipitation and temperatures. There is less agreement across models on a latitudinal shift, whose direction and magnitude correlate with changes in the vortex strength so that vortex weakening/strengthening corresponds to a southward/poleward shift of the vortex. Key Points: Model uncertainty contributes half of the total uncertainty in the projected strength of the Northern winter stratospheric polar vortexUncertainty in the projected polar vortex strength is linked to uncertainty in projected regional surface temperature and precipitationMost climate models project an eastward shift of the Northern winter stratospheric polar vortex [ABSTRACT FROM AUTHOR]

Published

2022

14. Uncertainty in the Winter Tropospheric Response to Arctic Sea Ice Loss: The Role of Stratospheric Polar Vortex Internal Variability.

Author

LANTAO SUN, DESER, CLARA, SIMPSON, ISLA, and SIGMOND, MICHAEL

Subjects

POLAR vortex, SEA ice, NORTH Atlantic oscillation, TROPOSPHERIC circulation, ROSSBY waves, ATMOSPHERIC models

Abstract

Arctic sea ice has declined rapidly over the past four decades and climate models project a seasonally icefree Arctic Ocean by the middle of this century, with attendant consequences for regional climate. However, modeling studies lack consensus on how the large-scale atmospheric circulation will respond to Arctic sea ice loss. In this study, the authors conduct a series of 200-member ensemble experiments with the Community Atmosphere Model version 6 (CAM6) to isolate the atmospheric response to past and future sea ice loss following the Polar Amplification Model Intercomparison Project (PAMIP) protocol. They find that the stratospheric polar vortex response is small compared to internal variability, which in turn influences the signal-to-noise ratio of the wintertime tropospheric circulation response to ice loss. In particular, a strong (weak) stratospheric polar vortex induces a positive (negative) tropospheric northern annular mode (and North Atlantic Oscillation), obscuring the forced component of the tropospheric response, even in 100-member averages. Stratospheric internal variability is closely tied to upward wave propagation from the troposphere and can be explained by linear wave interference between the anomalous and climatological planetary waves. Implications for the detection of recent observed trends and model realism are also presented. These results highlight the inherent uncertainty of the large-scale tropospheric circulation response to Arctic sea ice loss arising from stratospheric internal variability. [ABSTRACT FROM AUTHOR]

Published

2022

15. Response of the Quasi‐Biennial Oscillation to a warming climate in global climate models.

Author

Richter, Jadwiga H., Butchart, Neal, Kawatani, Yoshio, Bushell, Andrew C., Holt, Laura, Serva, Federico, Anstey, James, Simpson, Isla R., Osprey, Scott, Hamilton, Kevin, Braesicke, Peter, Cagnazzo, Chiara, Chen, Chih‐Chieh, Garcia, Rolando R., Gray, Lesley J., Kerzenmacher, Tobias, Lott, Francois, McLandress, Charles, Naoe, Hiroaki, and Scinocca, John

Subjects

GLOBAL warming, ATMOSPHERIC models, GRAVITY waves, GENERAL circulation model, OSCILLATIONS, QUASI-biennial oscillation (Meteorology)

Abstract

We compare the response of the Quasi‐Biennial Oscillation (QBO) to a warming climate in eleven atmosphere general circulation models that performed time‐slice simulations for present‐day, doubled, and quadrupled CO2 climates. No consistency was found among the models for the QBO period response, with the period decreasing by 8 months in some models and lengthening by up to 13 months in others in the doubled CO2 simulations. In the quadrupled CO2 simulations, a reduction in QBO period of 14 months was found in some models, whereas in several others the tropical oscillation no longer resembled the present‐day QBO, although it could still be identified in the deseasonalized zonal mean zonal wind timeseries. In contrast, all the models projected a decrease in the QBO amplitude in a warmer climate with the largest relative decrease near 60 hPa. In simulations with doubled and quadrupled CO2, the multi‐model mean QBO amplitudes decreased by 36 and 51%, respectively. Across the models the differences in the QBO period response were most strongly related to how the gravity wave momentum flux entering the stratosphere and tropical vertical residual velocity responded to the increases in CO2 amounts. Likewise it was found that the robust decrease in QBO amplitudes was correlated across the models to changes in vertical residual velocity, parametrized gravity wave momentum fluxes, and to some degree the resolved upward wave flux. We argue that uncertainty in the representation of the parameterized gravity waves is the most likely cause of the spread among the eleven models in the QBO's response to climate change. [ABSTRACT FROM AUTHOR]

Published

2022

16. Specified dynamics scheme impacts on wave-mean flow dynamics, convection, and tracer transport in CESM2 (WACCM6).

Author

Davis, Nicholas A., Callaghan, Patrick, Simpson, Isla R., and Tilmes, Simone

Subjects

CIRCULATION models, ATMOSPHERIC models, CHEMICAL weathering, METEOROLOGY, STRATOSPHERE

Abstract

Specified dynamics schemes are ubiquitous modeling tools for isolating the roles of dynamics and transport on chemical weather and climate. They typically constrain the circulation of a chemistry–climate model to the circulation in a reanalysis product through linear relaxation. However, recent studies suggest that these schemes create a divergence in chemical climate and the meridional circulation between models and do not accurately reproduce trends in the circulation. In this study we perform a systematic assessment of the specified dynamics scheme in the Community Earth System Model version 2, Whole Atmosphere Community Climate Model version 6 (CESM2 (WACCM6)), which proactively nudges the circulation toward the reference meteorology. Specified dynamics experiments are performed over a wide range of nudging timescales and reference meteorology frequencies, with the model's circulation nudged to its own free-running output – a clean test of the specified dynamics scheme. Errors in the circulation scale robustly and inversely with meteorology frequency and have little dependence on the nudging timescale. However, the circulation strength and errors in tracers, tracer transport, and convective mass flux scale robustly and inversely with the nudging timescale. A 12 to 24 h nudging timescale at the highest possible reference meteorology frequency minimizes errors in tracers, clouds, and the circulation, even up to the practical limit of one reference meteorology update every time step. The residual circulation and eddy mixing integrate tracer errors and accumulate them at the end of their characteristic transport pathways, leading to elevated error in the upper troposphere and lower stratosphere and in the polar stratosphere. Even in the most ideal case, there are non-negligible errors in tracers introduced by the nudging scheme. Future development of more sophisticated nudging schemes may be necessary for further progress. [ABSTRACT FROM AUTHOR]

Published

2022

17. A Minimal Model to Diagnose the Contribution of the Stratosphere to Tropospheric Forecast Skill.

Author

Charlton‐Perez, Andrew J., Bröcker, Jochen, Karpechko, Alexey Yu., Lee, Simon H., Sigmond, Michael, and Simpson, Isla R.

Subjects

STRATOSPHERE, OZONE layer, WEATHER forecasting, ATMOSPHERIC models

Abstract

Many recent studies have confirmed that variability in the stratosphere is a significant source of surface sub‐seasonal prediction skill during Northern Hemisphere winter. It may be beneficial, therefore, to think about times in which there might be windows‐of‐opportunity for skillfull sub‐seasonal predictions based on the initial or predicted state of the stratosphere. In this study, we propose a simple, minimal model that can be used to understand the impact of the stratosphere on tropospheric predictability. Our model purposefully excludes state dependent predictability in either the stratosphere or troposphere or in the coupling between the two. Model parameters are set up to broadly represent current sub‐seasonal prediction systems by comparison with four dynamical models from the Sub‐Seasonal to Seasonal Prediction Project database. The model can reproduce the increases in correlation skill in sub‐sets of forecasts for weak and strong lower stratospheric polar vortex states over neutral states despite the lack of dependence of coupling or predictability on the stratospheric state. We demonstrate why different forecast skill diagnostics can give a very different impression of the relative skill in the three sub‐sets. Forecasts with large stratospheric signals and low amounts of noise are demonstrated to also be windows‐of‐opportunity for skillfull tropospheric forecasts, but we show that these windows can be obscured by the presence of unrelated tropospheric signals. Plain Language Summary: For successful forecasts of surface winter conditions between two weeks and one season ahead, the stratosphere has been shown to be a key source of information. Despite many studies examining how well the stratosphere can be predicted in computer‐based forecasting systems, there remains a lack of understanding of which surface forecasts the stratosphere is most important for. This study is an attempt to step back from examining the role of the stratosphere in any particular forecasting system and instead to determine a simple framework that can be used to understand when and how the stratosphere is important. Using our framework we can construct a series of simple experiments that help to understand how important the stratosphere is in the longer range forecasting problem. Our experiments show that forecasts made during periods in which the Arctic stratospheric winds are unusually strong or weak have greater skill, but this does not depend on how unusually weak or strong the stratospheric winds are. The results are particularly important for thinking about the times in which longer range forecasts might be more skillfull than on average, so called windows‐of‐opportunity, and how these depend on the stratosphere. Key Points: We propose a model that demonstrates how forecast skill present in the lowermost stratosphere contributes to tropospheric forecast skillThe model can explain the greater correlation skill in the troposphere for forecasts during weak or strong vortex eventsThe model shows how tropospheric skill arising from the stratosphere can sometimes be confounded by uncorrelated tropospheric signals [ABSTRACT FROM AUTHOR]

Published

2021

18. The Influence of the Stratosphere on the Tropical Troposphere.

Author

HAYNES, Peter, HITCHCOCK, Peter, HITCHMAN, Matthew, Shigeo YODEN, HENDON, Harry, KILADIS, George, KODERA, Kunihiko, and SIMPSON, Isla

Subjects

STRATOSPHERE, TROPOSPHERE, OZONE layer, SEASONS, WEATHER forecasting, ATMOSPHERIC models

Abstract

Observational and model studies suggest that the stratosphere exerts a significant influence on the tropical troposphere. The corresponding influence, through dynamical coupling, of the stratosphere on the extratropical troposphere has over the last 15 - 20 years been intensively investigated, with consequent improvement in scientific understanding which is already being exploited by weather forecasting and climate prediction centres. The coupling requires both communication of dynamical effects from stratosphere to troposphere and feedbacks within the troposphere which enhance the tropospheric response. Scientific understanding of the influence of the stratosphere on the tropical troposphere is far less developed. This review summarises the current observational and modelling evidence for that influence, on timescales ranging from diurnal to centennial. The current understanding of potentially relevant mechanisms for communication and for feedbacks within the tropical troposphere and the possible implications of the coupling for weather and climate prediction are discussed. These include opportunities for model validation and for improved subseasonal and seasonal forecasting and the effects, for example, of changes in stratospheric ozone and of potential geoengineering approaches. Outstanding scientific questions are identified and future needs for observational and modelling work to resolve these questions are suggested. [ABSTRACT FROM AUTHOR]

Published

2021

19. Model Biases in the Simulation of the Springtime North Pacific ENSO Teleconnection.

Author

RUYAN CHEN, SIMPSON, ISLA R., DESER, CLARA, and BIN WANG

Subjects

*SPRING, *SOUTHERN oscillation, *ATMOSPHERIC models, EL Nino, LA Nina

Abstract

The wintertime ENSO teleconnection over the North Pacific region consists of an intensified (weakened) low pressure center during El Niño (La Niña) events both in observations and in climate models. Here, it is demonstrated that this teleconnection persists too strongly into late winter and spring in the Community Earth System Model (CESM). This discrepancy arises in both fully coupled and atmosphere-only configurations, when observed SSTs are specified, and is shown to be robust when accounting for the sampling uncertainty due to internal variability. Furthermore, a similar problem is found in many other models from piControl simulations of the Coupled Model Intercomparison Project (23 out of 43 in phase 5 and 11 out of 20 in phase 6). The implications of this bias for the simulation of surface climate anomalies over North America are assessed. The overall effect on the ENSO composite field (El Niño minus La Niña) resembles an overly prolonged influence of ENSO into the spring with anomalously high temperatures over Alaska and western Canada, and wet (dry) biases over California (southwest Canada). Further studies are still needed to disentangle the relative roles played by diabatic heating, background flow, and other possible contributions in determining the overly strong springtime ENSO teleconnection intensity over the North Pacific. [ABSTRACT FROM AUTHOR]

Published

2020

20. An Evaluation of the Large‐Scale Atmospheric Circulation and Its Variability in CESM2 and Other CMIP Models.

Author

Simpson, Isla R., Bacmeister, Julio, Neale, Richard B., Hannay, Cecile, Gettelman, Andrew, Garcia, Rolando R., Lauritzen, Peter H., Marsh, Daniel R., Mills, Michael J., Medeiros, Brian, and Richter, Jadwiga H.

Subjects

ATMOSPHERIC circulation, ATMOSPHERIC research, ATMOSPHERIC models, STANDING waves

Abstract

The Community Earth System Model 2 (CESM2) is the latest Earth System Model developed by the National Center for Atmospheric Research in collaboration with the university community and is significantly advanced in most components compared to its predecessor (CESM1). Here, CESM2's representation of the large‐scale atmospheric circulation and its variability is assessed. Further context is providedthrough comparison to the CESM1 large ensemble and other models from the Coupled Model Intercomparison Project (CMIP5 and CMIP6). This includes an assessment of the representation of jet streams and storm tracks, stationary waves, the global divergent circulation, the annular modes, the North Atlantic Oscillation, and blocking. Compared to CESM1, CESM2 is substantially improved in the representation of the storm tracks, Northern Hemisphere (NH) stationary waves, NH winter blocking and the global divergent circulation. It ranks within the top 10% of CMIP class models in many of these features. Some features of the Southern Hemisphere (SH) circulation have degraded, such as the SH jet strength, stationary waves, and blocking, although the SH jet stream is placed at approximately the correct location. This analysis also highlights systematic deficiencies in these features across the new CMIP6 archive, such as the continued tendency for the SH jet stream to be placed too far equatorward, the North Atlantic westerlies to be too strong over Europe, the storm tracks as measured by low‐level meridional wind variance to be too weak and a lack of blocking in the North Atlantic sector. Key Points: CESM2 is compared to CESM1 and other CMIP5 and CMIP6 models and ranks highly in many regardsJets, storm tracks, stationary waves, divergent circulation, NAM, SAM, NAO, and blocking are assessedCESM2 has improvements in storm tracks and NH winter circulation but degradations in SH circulation [ABSTRACT FROM AUTHOR]

Published

2020

21. The Lack of QBO‐MJO Connection in CMIP6 Models.

Author

Kim, Hyemi, Caron, Julie M., Richter, Jadwiga H., and Simpson, Isla R.

Subjects

ZONAL winds, ATMOSPHERIC models, LOW temperatures, STRATOSPHERE, MADDEN-Julian oscillation, TROPOPAUSE

Abstract

Observational analysis has indicated a strong connection between the stratospheric quasi‐biennial oscillation (QBO) and tropospheric Madden‐Julian oscillation (MJO), with MJO activity being stronger during the easterly phase than the westerly phase of the QBO. We assess the representation of this QBO‐MJO connection in 30 models participating in the Coupled Model Intercomparison Project 6. While some models reasonably simulate the QBO during boreal winter, none of them capture a difference in MJO activity between easterly and westerly QBO that is larger than that which would be expected from the random sampling of internal variability. The weak signal of the simulated QBO‐MJO connection may be due to the weaker amplitude of the QBO than observed, especially between 100 to 50 hPa. This weaker amplitude in the models is seen both in the QBO‐related zonal wind and temperature, the latter of which is thought to be critical for destabilizing tropical convection. Plain Language Summary: The QBO, which is a dominant mode of interannual variability in the tropical lower stratosphere, has been found to strongly modulate the MJO, a dominant mode of subseasonal variability in the tropical troposphere. We show that while half of the CMIP6 climate models simulate the QBO, none of them capture the observed QBO‐MJO relationship. The weak signal of the simulated QBO‐MJO relationship may be due to the models' weaker amplitude of the QBO‐related wind and temperature signal in the lower stratosphere, which is thought to be critical for modulating the MJO. Key Points: None of the CMIP6 models simulate the observed QBO‐MJO connectionSimulated MJO activity differences between QBO phases are consistent with sampling noiseModels have a weaker QBO signal near the tropopause than observed [ABSTRACT FROM AUTHOR]

Published

2020

22. Tropical Widening: From Global Variations to Regional Impacts.

Author

Staten, Paul W., Grise, Kevin M., Davis, Sean M., Karnauskas, Kristopher B., Waugh, Darryn W., Maycock, Amanda C., Qiang Fu, Cook, Kerry, Adam, Ori, Simpson, Isla R., Allen, Robert J., Rosenlof, Karen, Gang Chen, Ummenhofer, Caroline C., Xiao-Wei Quan, Kossin, James P., Davis, Nicholas A., and Seok-Woo Son

Subjects

OZONE layer, SPACE sciences, TEAMS in the workplace, TWENTY-first century, GREENHOUSE gases, ATMOSPHERIC models

Abstract

Over the past 15 years, numerous studies have suggested that the sinking branches of Earth's Hadley circulation and the associated subtropical dry zones have shifted poleward over the late twentieth century and early twenty-first century. Early estimates of this tropical widening from satellite observations and reanalyses varied from 0.25° to 3° latitude per decade, while estimates from global climate models show widening at the lower end of the observed range. In 2016, two working groups, the U.S. Climate Variability and Predictability (CLIVAR) working group on the Changing Width of the Tropical Belt and the International Space Science Institute (ISSI) Tropical Width Diagnostics Intercomparison Project, were formed to synthesize current understanding of the magnitude, causes, and impacts of the recent tropical widening evident in observations. These working groups concluded that the large rates of observed tropical widening noted by earlier studies resulted from their use of metrics that poorly capture changes in the Hadley circulation, or from the use of reanalyses that contained spurious trends. Accounting for these issues reduces the range of observed expansion rates to 0.25°-0.5° latitude decade-1--within the range from model simulations. Models indicate that most of the recent Northern Hemisphere tropical widening is consistent with natural variability, whereas increasing greenhouse gases and decreasing stratospheric ozone likely played an important role in Southern Hemisphere widening. Whatever the cause or rate of expansion, understanding the regional impacts of tropical widening requires additional work, as different forcings can produce different regional patterns of widening. [ABSTRACT FROM AUTHOR]

Published

2020

23. A Regime Perspective on the North Atlantic Eddy-Driven Jet Response to Sudden Stratospheric Warmings.

Author

Maycock, Amanda C., Masukwedza, Gibbon I. T., Hitchcock, Peter, and Simpson, Isla R.

Subjects

NORTH Atlantic oscillation, EDDY flux, MIDDLE atmosphere, HEAT flux, ATMOSPHERIC models, STRATOSPHERE

Abstract

Changes to the preferred states, or regime behavior, of the North Atlantic eddy-driven jet (EDJ) following a major sudden stratospheric warming (SSW) is examined using a large ensemble experiment from the Canadian Middle Atmosphere Model in which the stratosphere is nudged toward an SSW. In the 3 months following the SSW (January–March), the North Atlantic EDJ shifts equatorward by ~3°, on average; this arises from an increased occurrence of the EDJ's south regime and reductions in its north and central regimes. Qualitatively similar behavior is shown in a reanalysis dataset. We show that under SSW conditions the south regime becomes more persistent and that this can explain the overall increase in the EDJ latitude decorrelation time scale. A cluster analysis reveals that, following the SSW, the south EDJ regime is characterized by weaker low-level baroclinicity and eddy heat fluxes in the North Atlantic Ocean. We hypothesize, therefore, that the increased persistence of the south regime is related to the weaker baroclinicity leading to slower growth rates of the unstable modes and hence a slower buildup of eddy heat flux, which has been shown to precede EDJ transitions. In the North Atlantic sector, the surface response to the SSW projects onto a negative North Atlantic Oscillation (NAO) pattern, with almost no change in the east Atlantic (EA) pattern. This behavior appears to be distinct from the modeled intrinsic variability in the EDJ, where the jet latitude index captures variations in both the NAO and EA patterns. The results offer new insight into the mechanisms for stratosphere–troposphere coupling following SSWs. [ABSTRACT FROM AUTHOR]

Published

2020

24. Intermodel Spread in the Northern Hemisphere Stratospheric Polar Vortex Response to Climate Change in the CMIP5 Models.

Author

Wu, Yutian, Simpson, Isla R., and Seager, Richard

Subjects

*CLIMATE change models, *POLAR vortex, *STRATOSPHERIC circulation, *STANDING waves, *ATMOSPHERIC models, *THEORY of wave motion

Abstract

This study investigates the intermodel spread of the Northern Hemisphere winter stratospheric polar vortex change to anthropogenic greenhouse gas increase in Coupled Model Intercomparison Project Phase 5 (CMIP5) models. Previous proposed mechanisms for the polar vortex response to climate change, based on analysis of atmosphere‐only models, are found inadequate to explain the intermodel spread in the coupled models in CMIP5. It is further found that resolved stationary wave driving in the polar vortex region accounts for less than 30% of the intermodel spread, and intermodel differences in both the vertical and meridional wave propagation contribute to differences in the wave driving. The results call for a detailed budget analysis of the stratospheric circulation response by including both the resolved and parameterized processes through the Dynamics and Variability Model Intercomparison Project. The results also highlight a need for an improved theoretical understanding of future projected polar vortex change and intermodel spread. Plain Language Summary: It has been increasingly recognized that the stratospheric circulation can significantly affect the troposphere and the surface through a downward influence, and thus, it is important to predict and understand how the stratospheric circulation will respond to anthropogenic greenhouse gas increase. However, there is a large disagreement in the stratospheric circulation response to climate change among the current generation of climate models. This study determines that previously proposed mechanisms to explain the intermodel spread are inadequate and, therefore, motivates an improved understanding of the stratospheric circulation response and model‐to‐model differences. This is a goal that should be achieved through forthcoming model intercomparison efforts. Key Points: Resolved stationary wave driving accounts for less than 30% of the intermodel spread in the stratospheric polar vortex change in CMIP5Both altered vertical wave propagation into the stratosphere and altered meridional propagation within the stratosphere contributeProposed theories for the stratospheric polar vortex response to climate change appear inadequate to explain the intermodel spread in CMIP5 [ABSTRACT FROM AUTHOR]

Published

2019

25. CESM1(WACCM) Stratospheric Aerosol Geoengineering Large Ensemble Project.

Author

Tilmes, Simone, Richter, Jadwiga H., Kravitz, Ben, MacMartin, Douglas G., Mills, Michael J., Simpson, Isla R., Glanville, Anne S., Fasullo, John T., Phillips, Adam S., Lamarque, Jean-Francois, Tribbia, Joseph, Edwards, Jim, Mickelson, Sheri, and Ghosh, Siddhartha

Subjects

ATMOSPHERIC aerosols, ATMOSPHERIC models, CLIMATE change, STRATOSPHERE, WEATHER forecasting

Abstract

This paper describes the Stratospheric Aerosol Geoengineering Large Ensemble (GLENS) project, which promotes the use of a unique model dataset, performed with the Community Earth System Model, with the Whole Atmosphere Community Climate Model as its atmospheric component [CESM1(WACCM)], to investigate global and regional impacts of geoengineering. The performed simulations were designed to achieve multiple simultaneous climate goals, by strategically placing sulfur injections at four different locations in the stratosphere, unlike many earlier studies that targeted globally averaged surface temperature by placing injections in regions at or around the equator. This advanced approach reduces some of the previously found adverse effects of stratospheric aerosol geoengineering, including uneven cooling between the poles and the equator and shifts in tropical precipitation. The 20-member ensemble increases the ability to distinguish between forced changes and changes due to climate variability in global and regional climate variables in the coupled atmosphere, land, sea ice, and ocean system. We invite the broader community to perform in-depth analyses of climate-related impacts and to identify processes that lead to changes in the climate system as the result of a strategic application of stratospheric aerosol geoengineering. [ABSTRACT FROM AUTHOR]

Published

2018

26. Modeled and Observed Multidecadal Variability in the North Atlantic Jet Stream and Its Connection to Sea Surface Temperatures.

Author

Simpson, Isla R., Deser, Clara, McKinnon, Karen A., and Barnes, Elizabeth A.

Subjects

*OCEAN temperature, *JET streams, *ATMOSPHERIC models, *NORTH Atlantic oscillation, *COMPUTER simulation

Abstract

Multidecadal variability in the North Atlantic jet stream in general circulation models (GCMs) is compared with that in reanalysis products of the twentieth century. It is found that almost all models exhibit multidecadal jet stream variability that is entirely consistent with the sampling of white noise year-to-year atmospheric fluctuations. In the observed record, the variability displays a pronounced seasonality within the winter months, with greatly enhanced variability toward the late winter. This late winter variability exceeds that found in any GCM and greatly exceeds expectations from the sampling of atmospheric noise, motivating the need for an underlying explanation. The potential roles of both external forcings and internal coupled ocean–atmosphere processes are considered. While the late winter variability is not found to be closely connected with external forcing, it is found to be strongly related to the internally generated component of Atlantic multidecadal variability (AMV) in sea surface temperatures (SSTs). In fact, consideration of the seasonality of the jet stream variability within the winter months reveals that the AMV is far more strongly connected to jet stream variability during March than the early winter months or the winter season as a whole. Reasoning is put forward for why this connection likely represents a driving of the jet stream variability by the SSTs, although the dynamics involved remain to be understood. This analysis reveals a fundamental mismatch between late winter jet stream variability in observations and GCMs and a potential source of long-term predictability of the late winter Atlantic atmospheric circulation. [ABSTRACT FROM AUTHOR]

Published

2018

27. The TropD software package (v1): standardized methods for calculating tropical-width diagnostics.

Author

Adam, Ori, Grise, Kevin M., Staten, Paul, Simpson, Isla R., Davis, Sean M., Davis, Nicholas A., Waugh, Darryn W., Birner, Thomas, and Ming, Alison

Subjects

METEOROLOGICAL observations, ATMOSPHERIC models, SENSITIVITY analysis, COMPUTER software, ENVIRONMENTAL sciences

Abstract

Observational and modeling studies suggest that Earth's tropical belt has widened over the late 20th century and will continue to widen throughout the 21st century. Yet, estimates of tropical-width variations differ significantly across studies. This uncertainty, to an unknown degree, is partly due to the large variety of methods used in studies of the tropical width. Here, methods for eight commonly used metrics of the tropical width are implemented in the Tropical-width Diagnostics (TropD) code package in the MATLAB programming language. To consolidate the various methods, the operations used in each of the implemented methods are reduced to two basic calculations: finding the latitude of a zero crossing and finding the latitude of a maximum. A detailed description of the methods implemented in the code and of the code syntax is provided, followed by a method sensitivity analysis for each of the metrics. The analysis provides information on how to reduce the methodological component of the uncertainty associated with fundamental aspects of the calculations, such as monthly vs. seasonal averaging biases, grid dependence, sensitivity to noise, and sensitivity to threshold criteria. [ABSTRACT FROM AUTHOR]

Published

2018

28. The Downward Influence of Uncertainty in the Northern Hemisphere Stratospheric Polar Vortex Response to Climate Change.

Author

Simpson, Isla R, Hitchcock, Peter, Seager, Richard, Wu, Yutian, and Callaghan, Patrick

Subjects

*ATMOSPHERIC circulation, *ATMOSPHERIC physics, *CLIMATOLOGY, *CLIMATE change, *POLAR vortex, *ATMOSPHERIC models

Abstract

General circulation models display a wide range of future predicted changes in the Northern Hemisphere winter stratospheric polar vortex. The downward influence of this stratospheric uncertainty on the troposphere has previously been inferred from regression analyses across models and is thought to contribute to model spread in tropospheric circulation change. Here we complement such regression analyses with idealized experiments using one model where different changes in the zonal-mean stratospheric polar vortex are artificially imposed to mimic the extreme ends of polar vortex change simulated by models from phase 5 of the Coupled Model Intercomparison Project (CMIP5). The influence of the stratospheric vortex change on the tropospheric circulation in these experiments is quantitatively in agreement with the inferred downward influence from across-model regressions, indicating that such regressions depict a true downward influence of stratospheric vortex change on the troposphere below. With a relative weakening of the polar vortex comes a relative increase in Arctic sea level pressure (SLP), a decrease in zonal wind over the North Atlantic, drying over northern Europe, and wetting over southern Europe. The contribution of stratospheric vortex change to intermodel spread in these quantities is assessed in the CMIP5 models. The spread, as given by 4 times the across-model standard deviation, is reduced by roughly 10% on regressing out the contribution from stratospheric vortex change, while the difference between models on extreme ends of the distribution in terms of their stratospheric vortex change can reach up to 50% of the overall model spread for Arctic SLP and 20% of the overall spread in European precipitation. [ABSTRACT FROM AUTHOR]

Published

2018

29. The Northern Hemisphere Extratropical Atmospheric Circulation Response to ENSO: How Well Do We Know It and How Do We Evaluate Models Accordingly?

Author

Deser, Clara, Simpson, Isla R., McKinnon, Karen A., and Phillips, Adam S.

Subjects

*ATMOSPHERIC circulation, *STATISTICAL sampling, *ATMOSPHERIC models, *TELECONNECTIONS (Climatology)

Abstract

Application of random sampling techniques to composite differences between 18 El Niño and 14 La Niña events observed since 1920 reveals considerable uncertainty in both the pattern and amplitude of the Northern Hemisphere extratropical winter sea level pressure (SLP) response to ENSO. While the SLP responses over the North Pacific and North America are robust to sampling variability, their magnitudes can vary by a factor of 2; other regions, such as the Arctic, North Atlantic, and Europe are less robust in their SLP patterns, amplitudes, and statistical significance. The uncertainties on the observed ENSO composite are shown to arise mainly from atmospheric internal variability as opposed to ENSO diversity. These observational findings pose considerable challenges for the evaluation of ENSO teleconnections in models. An approach is proposed that incorporates both pattern and amplitude uncertainty in the observational target, allowing for discrimination between true model biases in the forced ENSO response and apparent model biases that arise from limited sampling of non-ENSO-related internal variability. Large initial-condition coupled model ensembles with realistic tropical Pacific sea surface temperature anomaly evolution during 1920-2013 show similar levels of uncertainty in their ENSO teleconnections as found in observations. Because the set of ENSO events in each of the model composites is the same (and identical to that in observations), these uncertainties are entirely attributable to sampling fluctuations arising from internal variability, which is shown to originate from atmospheric processes. The initial-condition model ensembles thus inform the interpretation of the single observed ENSO composite and vice versa. [ABSTRACT FROM AUTHOR]

Published

2017

30. The Downward Influence of Stratospheric Sudden Warmings*.

Author

Hitchcock, Peter and Simpson, Isla R.

Subjects

*STRATOSPHERE, *CHEMOSPHERE, *TROPOSPHERE, *ATMOSPHERE, *ATMOSPHERIC models, *ATMOSPHERIC sciences

Abstract

The coupling between the stratosphere and the troposphere following two major stratospheric sudden warmings is studied in the Canadian Middle Atmosphere Model using a nudging technique by which the zonal-mean evolution of the reference sudden warmings are artificially induced in an ~100-member ensemble spun off from a control simulation. Both reference warmings are taken from a freely running integration of the model. One event is a displacement, the other is a split, and both are followed by extended recoveries in the lower stratosphere. The methodology permits a statistically robust study of their influence on the troposphere below. The nudged ensembles exhibit a tropospheric annular mode response closely analogous to that seen in observations, confirming the downward influence of sudden warmings on the troposphere in a comprehensive model. This tropospheric response coincides more closely with the lower-stratospheric annular mode anomalies than with the midstratospheric wind reversal. In addition to the expected synoptic-scale eddy feedback, the planetary-scale eddies also reinforce the tropospheric wind changes, apparently responding directly to the stratospheric anomalies. Furthermore, despite the zonal symmetry of the stratospheric perturbation, a highly zonally asymmetric near-surface response is produced, corresponding to a strongly negative phase of the North Atlantic Oscillation with a much weaker response over the Pacific basin that matches composites of sudden warmings from the Interim ECMWF Re-Analysis (ERA-Interim). Phase 5 of the Coupled Model Intercomparison Project models exhibit a similar response, though in most models the response's magnitude is underrepresented. [ABSTRACT FROM AUTHOR]

Published

2014

31. Southern Annular Mode Dynamics in Observations and Models. Part II: Eddy Feedbacks.

Author

Simpson, Isla R., Shepherd, Theodore G., Hitchcock, Peter, and Scinocca, John F.

Subjects

*ATMOSPHERIC models, *EDDY flux, *SIMULATION methods & models, *SUMMER, *RADIATIVE forcing

Abstract

Many global climate models (GCMs) have trouble simulating southern annular mode (SAM) variability correctly, particularly in the Southern Hemisphere summer season where it tends to be too persistent. In this two-part study, a suite of experiments with the Canadian Middle Atmosphere Model (CMAM) is analyzed to improve the understanding of the dynamics of SAM variability and its deficiencies in GCMs. Here, an examination of the eddy-mean flow feedbacks is presented by quantification of the feedback strength as a function of zonal scale and season using a new methodology that accounts for intraseasonal forcing of the SAM. In the observed atmosphere, in the summer season, a strong negative feedback by planetary-scale waves, in particular zonal wavenumber 3, is found in a localized region in the southwest Pacific. It cancels a large proportion of the positive feedback by synoptic- and smaller-scale eddies in the zonal mean, resulting in a very weak overall eddy feedback on the SAM. CMAM is deficient in this negative feedback by planetary-scale waves, making a substantial contribution to its bias in summertime SAM persistence. Furthermore, this bias is not alleviated by artificially improving the climatological circulation, suggesting that climatological circulation biases are not the cause of the planetary wave feedback deficiency in the model. Analysis of the summertime eddy feedbacks in the models from phase 5 of the Coupled Model Intercomparison Project (CMIP5) confirms that this is indeed a common problem among GCMs, suggesting that understanding this planetary wave feedback and the reason for its deficiency in GCMs is key to improving the fidelity of simulated SAM variability in the summer season. [ABSTRACT FROM AUTHOR]

Published

2013