Tropical Cyclone Climatology in a 10-km Global Atmospheric GCM: Toward Weather-Resolving Climate Modeling

Manganello, Julia V.; Hodges, Kevin I.; Kinter, James L.; Cash, Benjamin A.; Marx, L.; Jung, Thomas; Achuthavarier, Deepthi; Adams, Jennifer; Altshuler, Eric L.; Huang, Bohua; Jin, Emilia Kyung; Stan, Cristiana; Towers, Peter; Wedi, Nils

doi:10.1175/jcli-d-11-00346.1

Cited by 175 publications

(242 citation statements)

References 69 publications

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“…There is mounting evidence from many modeling studies that atmosphere resolutions at 50 km or finer skillfully represent the interannual variability of tropical cyclones (Zhao et al 2009;Manganello et al 2012;Roberts et al 2015;Kodama et al 2015). In the Atlantic, much of this improvement can be attributed to better global teleconnections (from El Niño; e.g., Bell et al 2014) providing a constraint on the environment and improved dynamical precursor features such as African easterly waves (AEWs).…”

Section: The Global Hydrological Cyclementioning

confidence: 99%

“…More recently the grid spacing in state-of-the-art global models has become sufficiently fine (of order 10-30 km) to realistically represent TCs, even in terms of intensity (Manganello et al 2012;Wehner et al 2014Wehner et al , 2015Murakami et al 2015;Walsh et al 2015;Scoccimarro 2016;Scoccimarro et al 2017), up to the maximum category 5. Our current understanding of future changes to frequency and intensity (Walsh et al 2015) is based on these relatively few capable models, hence indicating a more systematic and multimodel study is required to increase our confidence in such interpretations.…”

Section: The Global Hydrological Cyclementioning

confidence: 99%

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The Benefits of Global High Resolution for Climate Simulation: Process Understanding and the Enabling of Stakeholder Decisions at the Regional Scale

Roberts

Vidale

Senior

et al. 2018

Bulletin of the American Meteorological Society

128

107

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The time scales of the Paris Climate Agreement indicate urgent action is required on climate policies over the next few decades, in order to avoid the worst risks posed by climate change. On these relatively short time scales the combined effect of climate variability and change are both key drivers of extreme events, with decadal time scales also important for infrastructure planning. Hence, in order to assess climate risk on such time scales, we require climate models to be able to represent key aspects of both internally driven climate variability and the response to changing forcings. In this paper we argue that we now have the modeling capability to address these requirements—specifically with global models having horizontal resolutions considerably enhanced from those typically used in previous Intergovernmental Panel on Climate Change (IPCC) and Coupled Model Intercomparison Project (CMIP) exercises. The improved representation of weather and climate processes in such models underpins our enhanced confidence in predictions and projections, as well as providing improved forcing to regional models, which are better able to represent local-scale extremes (such as convective precipitation). We choose the global water cycle as an illustrative example because it is governed by a chain of processes for which there is growing evidence of the benefits of higher resolution. At the same time it comprises key processes involved in many of the expected future climate extremes (e.g., flooding, drought, tropical and midlatitude storms).

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Section: The Global Hydrological Cyclementioning

confidence: 99%

Section: The Global Hydrological Cyclementioning

confidence: 99%

The Benefits of Global High Resolution for Climate Simulation: Process Understanding and the Enabling of Stakeholder Decisions at the Regional Scale

Roberts

Vidale

Senior

et al. 2018

Bulletin of the American Meteorological Society

128

107

View full text Add to dashboard Cite

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“…Error statistics based on this measure is shown to be consistent with more traditional verification metrics [see Hodges and Emerton, 2015]. In addition, 10 m wind speed and minimum sea level pressure (SLP) were compared against the IBTrACS (Figure 9) because these quantities are underestimated in the CFSR data due to the model's resolution [e.g., Manganello et al, 2012]. …”

Section: Journal Of Advances In Modeling Earth Systems 101002/2016msmentioning

confidence: 85%

“…Recent advancements in high performance computing represent an exciting opportunity for global climate model development, pushing the limits of representing clouds and convection in a global atmospheric model [Chen and Lin, 2011;Dirmeyer et al, 2012;Manganello et al, 2012;Murakami et al, 2012;Bacmeister et al, 2014;Wehner et al, 2014]. As a consequence, atmospheric moist convection can now be represented in sophisticated schemes such as global cloud-resolving models and super parameterization schemes [Grabowski, 2001;Khairoutdinov and Randall, 2001;Randall et al, 2003;Tomita and Satoh, 2004;Satoh et al, 2008Satoh et al, , 2014Stan et al, 2010].…”

Section: Introductionmentioning

confidence: 99%

The heated condensation framework as a convective trigger in the NCEP Climate Forecast System version 2

Bombardi

Tawfik

Manganello

et al. 2016

J Adv Model Earth Syst

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An updated version of the Heated Condensation Framework (HCF) is implemented as a convective triggering criterion into the National Centers for Environmental Prediction (NCEP) Climate Forecast System version 2 (CFSv2). The new trigger replaces the original criteria in both the deep (Simplified Arakawa‐Schubert – SAS) and shallow (SAS based) convective schemes. The performance of the original and new triggering criteria is first compared against radiosonde observations. Then, a series of hindcasts are performed to evaluate the influence of the triggering criterion in the CFSv2 representation of summer precipitation, the diurnal cycle of precipitation, and hurricanes that made landfall. The observational analysis shows that the HCF trigger better captures the frequency of convection, where the original SAS trigger initiates convection too often. When implemented in CFSv2, the HCF trigger improves the seasonal forecast of the Indian summer monsoon rainfall, including the representation of the onset dates of the rainy season over India. On the other hand, the HCF trigger increases error in the seasonal forecast of precipitation over the eastern United States. The HCF trigger also improves the representation of the intensity of hurricanes. Moreover, the simulation of hurricanes provides insights on the mechanism whereby the HCF trigger impacts the representation of convection.

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“…Importantly, the MRI-AGCM, GFDL-HiRAM, and FSU-COAPS Strazzo et al [2015] suggest that model errors in larger scale features are partially to blame. Manganello et al [2012] attribute the inability of the ECMWF integrated forecast system to capture the observed spatial distribution of TC activity to model errors in the large-scale environmental conditions. Furthermore, they show that these errors tend to be fairly consistent regardless of the resolution used for the model run.…”

Section: Summary and Discussionmentioning

confidence: 99%

The influence of model resolution on the simulated sensitivity of North Atlantic tropical cyclone maximum intensity to sea surface temperature

Strazzo

Elsner

LaRow³

et al. 2016

J Adv Model Earth Syst

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Global climate models (GCMs) are routinely relied upon to study the possible impacts of climate change on a wide range of meteorological phenomena, including tropical cyclones (TCs). Previous studies addressed whether GCMs are capable of reproducing observed TC frequency and intensity distributions. This research builds upon earlier studies by examining how well GCMs capture the physically relevant relationship between TC intensity and SST. Specifically, the influence of model resolution on the ability of a GCM to reproduce the sensitivity of simulated TC intensity to SST is examined for the MRI‐AGCM (20 km), the GFDL‐HiRAM (50 km), the FSU‐COAPS (0.94°) model, and two versions of the CAM5 (1° and 0.25°). Results indicate that while a 1°C increase in SST corresponds to a 5.5–7.0 m s−1 increase in observed maximum intensity, the same 1°C increase in SST is not associated with a statistically significant increase in simulated TC maximum intensity for any of the models examined. However, it also is shown that the GCMs all capably reproduce the observed sensitivity of potential intensity to SST. The models generate the thermodynamic environment suitable for the development of strong TCs over the correct portions of the North Atlantic basin, but strong simulated TCs do not develop over these areas, even for models that permit Category 5 TCs. This result supports the notion that direct simulation of TC eyewall convection is necessary to accurately represent TC intensity and intensification processes in climate models, although additional explanations are also explored.

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Tropical Cyclone Climatology in a 10-km Global Atmospheric GCM: Toward Weather-Resolving Climate Modeling

Cited by 175 publications

References 69 publications

The Benefits of Global High Resolution for Climate Simulation: Process Understanding and the Enabling of Stakeholder Decisions at the Regional Scale

The Benefits of Global High Resolution for Climate Simulation: Process Understanding and the Enabling of Stakeholder Decisions at the Regional Scale

The heated condensation framework as a convective trigger in the NCEP Climate Forecast System version 2

The influence of model resolution on the simulated sensitivity of North Atlantic tropical cyclone maximum intensity to sea surface temperature

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