Alleviation of a systematic westerly bias in general circulation and numerical weather prediction models through an orographic gravity wave drag parametrization

Palmer, Tim; Shutts, G. J.; Swinbank, Richard

doi:10.1002/qj.49711247406

Cited by 703 publications

(459 citation statements)

References 46 publications

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“…The large-scale precipitation is calculated using the Zhao and Carr (1997) scheme and shallow convection is parameterized using the scheme of Li (1994). Gravity wave drag effects are calculated using Palmer et al (1986).…”

Section: Overview Of the Cwb Agcmmentioning

confidence: 99%

A Source of AGCM Bias in Simulating the Western Pacific Subtropical High: Different Sensitivities to the Two Types of ENSO

Paek

Hwu³

et al. 2015

Monthly Weather Review

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This study reveals a possible cause of model bias in simulating the western Pacific subtropical high (WPSH) variability via an examination of an Atmospheric Model Intercomparison Project (AMIP) simulation produced by the atmospheric general circulation model (AGCM) developed at Taiwan's Central Weather Bureau (CWB). During boreal summer, the model overestimates the quasi-biennial (2-3 yr) band of WPSH variability but underestimates the low-frequency (3-5 yr) band of variability. The overestimation of the quasibiennial WPSH sensitivity is found to be due to the model's stronger sensitivity to the central Pacific El Niño-Southern Oscillation (CP ENSO) that has a leading periodicity in the quasi-biennial band. The model underestimates the low-frequency WPSH variability because of its weaker sensitivity to the eastern Pacific (EP) ENSO that has a leading periodicity in the 3-5-yr band. These different model sensitivities are shown to be related to the relative strengths of the mean Hadley and Walker circulations simulated in the model. An overly strong Hadley circulation causes the CWB AGCM to be overly sensitive to the CP ENSO, while an overly weak Walker circulation results in a weak sensitivity to the EP ENSO. The relative strengths of the simulated mean Hadley and Walker circulations are critical to a realistic simulation of the summer WPSH variability in AGCMs. This conclusion is further supported using AMIP simulations produced by three other AGCMs, including the CanAM4, GISS-E2-R, and IPSL-CM5A-MR models.

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Section: Overview Of the Cwb Agcmmentioning

confidence: 99%

A Source of AGCM Bias in Simulating the Western Pacific Subtropical High: Different Sensitivities to the Two Types of ENSO

Paek

Hwu³

et al. 2015

Monthly Weather Review

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“…The radiation scheme is that of Morcrette (1990) and includes a predictive cloud scheme based on relative humidity criteria (Slingo 1987). The gravity wave drag scheme of Palmer et al (1986) is used. The vertical advection uses a total variance diminishing scheme (Thuburn 1993).…”

Section: The Model and Boundary Conditionsmentioning

confidence: 99%

A GCM Simulation of the Climate 6000 Years Ago

Hall¹,

Valdes

1997

J. Climate

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Two 10-yr integrations of the UGAMP GCM are presented. Each has a full seasonal cycle, T42 resolution, interactive land and sea ice, and prescribed sea surface temperatures. They differ in that one integration represents present day climate (PD) and the other has a perturbed orbit and reduced atmospheric concentrations of CO 2 appropriate to the climate of 6000 years ago (6 kyr, hereafter 6k). The 6k integration produces enhanced continental warmth during summer and cold during winter. Changes in atmospheric temperature gradients brought about by the surface response lead to altered jet stream structures and transient eddy activity, which in turn affect precipitation patterns. Tropical ''monsoon''-type circulation patterns are also affected, also leading to altered precipitation. Many of the changes in hydrology mimic the geological record remarkably well: the Sahel is much wetter, as are the midwestern United States and the Mediterranean regions; California and northern Europe are drier. Processes leading to the model's surface responses in both temperature and hydrology are described in detail. Finally, the sensitivity of the results to an alternative, objective definition of the 6k calendar is investigated. This sensitivity is found to be smaller than the overall signal to the extent that the principal conclusions are not altered.

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“…Even so, its influence is important to represent, particularly the component due to orographic gravity waves. Prior to the introduction of orographic gravity wave drag parametrization in the 1980s (Palmer et al, 1986;McFarlane, 1987), NWP models were prone to excessively strong westerly flow, particularly at low levels in the Northern Hemisphere winter. It became clear some years later that a substantial component of the missing surface drag was actually associated with mesoscale mountain barriers and flow-blocking dynamics rather than gravity wave dynamics (e.g.…”

Section: Introductionmentioning

confidence: 99%

Stratospheric gravity waves revealed in NWP model forecasts

Shutts¹

2011

Quart J Royal Meteoro Soc

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Current operational numerical weather prediction models potentially have sufficient spatial and temporal resolution to resolve much of the inertia-gravity wave spectrum (e.g. horizontal wavelengths in the region of 100-1000 km typically, and even longer zonal wavelengths in the Tropics). The effects of gravity wave dynamics are usually considered to be subgrid-scale and parametrizable, either as stationary, mountain waves or travelling, non-orographic waves. Simple techniques for isolating these waves in both the

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Alleviation of a systematic westerly bias in general circulation and numerical weather prediction models through an orographic gravity wave drag parametrization

Cited by 703 publications

References 46 publications

A Source of AGCM Bias in Simulating the Western Pacific Subtropical High: Different Sensitivities to the Two Types of ENSO

A Source of AGCM Bias in Simulating the Western Pacific Subtropical High: Different Sensitivities to the Two Types of ENSO

A GCM Simulation of the Climate 6000 Years Ago

Stratospheric gravity waves revealed in NWP model forecasts

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