Robust future precipitation declines in CMIP5 largely reflect the poleward expansion of model subtropical dry zones

Scheff, Jacob; Frierson, Dargan M. W.

doi:10.1029/2012gl052910

Cited by 161 publications

(134 citation statements)

References 22 publications

(46 reference statements)

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“…Finally, we have shown that the leading pattern of uncertainty in the trends of the mean meridional circulation is able to explain most of the leading pattern of uncertainty in the trends of the hydrological (P 2 E) cycle, in the tropics and the extratropics, and in both seasons. A similar strong linkage between projected changes in precipitation and changes in the atmospheric circulation has recently been reported by Scheff and Frierson (2012).…”

Section: Discussionsupporting

confidence: 82%

Uncertainty in Climate Change Projections of the Hadley Circulation: The Role of Internal Variability

2013

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The uncertainty arising from internal climate variability in climate change projections of the Hadley circulation (HC) is presently unknown. In this paper it is quantified by analyzing a 40-member ensemble of integrations of the Community Climate System Model, version 3 (CCSM3), under the Special Report on Emissions Scenarios (SRES) A1B scenario over the period 2000-60. An additional set of 100-yr-long timeslice integrations with the atmospheric component of the same model [Community Atmosphere Model, version 3.0 (CAM3)] is also analyzed.Focusing on simple metrics of the HC-its strength, width, and height-three key results emerge from the analysis of the CCSM3 ensemble. First, the projected weakening of the HC is almost entirely confined to the Northern Hemisphere, and is stronger in winter than in summer. Second, the projected widening of the HC occurs only in the winter season but in both hemispheres. Third, the projected rise of the tropical tropopause occurs in both hemispheres and in all seasons and is, by far, the most robust of the three metrics. This paper shows further that uncertainty in future trends of the HC width is largely controlled by extratropical variability, while those of HC strength and height are associated primarily with tropical dynamics. Comparison of the CCSM3 and CAM3 integrations reveals that ocean-atmosphere coupling is the dominant source of uncertainty in future trends of HC strength and height and of the tropical mean meridional circulation in general. Finally, uncertainty in future trends of the hydrological cycle is largely captured by the uncertainty in future trends of the mean meridional circulation.

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Section: Discussionsupporting

confidence: 82%

Uncertainty in Climate Change Projections of the Hadley Circulation: The Role of Internal Variability

2013

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“…A strong negative correlation was identified between ECS and the mean May through August RH of the middle and upper troposphere in winter hemisphere subtropics in the CMIP3 models. It was reasoned that the processes drying the troposphere served as an indicator of the interaction between moisture and the tropical circulation and that a connection to future projections existed via the expansion of such dry zones with warming (e.g., [33]) and an associated reduction of clouds. A connection between ECS and the intensities of shallow and deep components of the Hadley circulation was also found.…”

Section: Cloud-related Ecsmentioning

confidence: 99%

Recent Progress in Constraining Climate Sensitivity With Model Ensembles

Fasullo

Sanderson

Trenberth

2015

Curr Clim Change Rep

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Recently available model ensembles have created an unprecedented opportunity for exploring and narrowing uncertainty in one of climate's benchmark indices, equilibrium climate sensitivity. A range of novel approaches for constraining the raw sensitivity estimates from these ensembles with observations has also been proposed, applied, and explored in a diversity of contexts. Through subsequent analysis, an increased understanding of the relative merits and limitations of these methods has been gained and their refinement and optimal implementation continue to be actively studied and debated with the hopes of reducing uncertainty in one of climate science's most persistent and elusive measures.

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“…To the first order, these trends result from the EÀP forcing increase in positive EÀP regions as expected by the Clausius Clapeyron relationship in a warming world [Held and Soden, 2006;Seager et al, 2010]. Recent model studies further suggest that not only the amplitude but also the location of the maximum EÀP forcing may change in the future climate in response to global warming [Seager et al, 2010;Scheff and Frierson, 2012]. It is thus crucial to monitor SSS changes in these cores in order to better understand their relationship to climate change.…”

Section: Introductionmentioning

confidence: 99%

Formation and variability of the South Pacific Sea Surface Salinity maximum in recent decades

Hasson

Delcroix

Boutin

2013

J. Geophys. Res. Oceans

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International audienceThis study investigates causes for the formation and variability of the Sea Surface Salinity maximum (SSS > 36) centered near 18°S-124°W in the South Pacific Ocean over the 1990-2011 period at the seasonal time scale and above. We use two monthly gridded products of SSS based on in situ measurements, high-resolution along-track Voluntary Observing Ships thermo-salinograph data, new SMOS satellite data, and a validated ocean general circulation model with no direct SSS relaxation. All products reveal a seasonal cycle of the location of the 36-isohaline barycenter of about ±400 km in longitude in response to changes in the South Pacific Convergence Zone location and Easterly winds intensity. They also show a low frequency westward shift of the barycenter of 1400 km from the mid 1990s to the early 2010s that could not be linked to the El Nino Southern Oscillation phenomena. In the model, the processes maintaining the 22 year equilibrium of the high salinity in the mixed layer are the surface forcing (˜+0.73 pss/yr), the horizontal salinity advection (˜-0.37 pss/yr), and processes occurring at the mixed layer base (˜-0.35 pss/yr)

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Robust future precipitation declines in CMIP5 largely reflect the poleward expansion of model subtropical dry zones

Cited by 161 publications

References 22 publications

Uncertainty in Climate Change Projections of the Hadley Circulation: The Role of Internal Variability

Uncertainty in Climate Change Projections of the Hadley Circulation: The Role of Internal Variability

Recent Progress in Constraining Climate Sensitivity With Model Ensembles

Formation and variability of the South Pacific Sea Surface Salinity maximum in recent decades

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