General circulation of the atmosphere

Arakawa, Akio

doi:10.1029/rg013i003p00668

Cited by 3 publications

(1 citation statement)

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“…One of the major challenges in CGCMs for the simulation of MJO as well as ISO is the poor representation of cloud processes in the parameterization scheme (Hazra, Chaudhari, Saha, & Pokhrel, 2017; Hazra, Chaudhari, Saha, Pokhrel, & Goswami, 2017; Lee et al., 2003; Maloney, 2002; Maloney & Hartmann, 2001). This is because they are convectively coupled phenomena and cloud feedback plays an important role in those processes (Arakawa 1975, 2004; Frank, 1983; Randall et al., 2003). The biases in the mean rainfall structure in the Indian Ocean (Sperber & Annamalai, 2008) and unrealistic Ocean‐atmospheric coupling (Hendon, 2000; Waliser et al., 1999) are also responsible in this connection.…”

Section: Introductionmentioning

confidence: 99%

Role of Microphysics and Convective Autoconversion for the Better Simulation of Tropical Intraseasonal Oscillations (MISO and MJO)

Dutta

Hazra

Chaudhari

et al. 2021

J Adv Model Earth Syst

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Section: Introductionmentioning

confidence: 99%

Role of Microphysics and Convective Autoconversion for the Better Simulation of Tropical Intraseasonal Oscillations (MISO and MJO)

Dutta

Hazra

Chaudhari

et al. 2021

J Adv Model Earth Syst

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A non‐linear atmospheric long wave model incorporating parametrizations of transient baroclinic eddies

White

Green

1982

Quart J Royal Meteoro Soc

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SUMMARYNumerical experiments with a simple spectral model of tropospheric long waves are described. The model is based on the 2-parameter, ,%plane, quasi-geostrophic equations and a coarse truncation is applied. Transient baroclinic eddy motion is represented parametrically using transfer coefficient expressions which are extensions of those proposed by Green in 1970 for zonal average formulations. The long waves are forced directly by externally specified diabatic and orographic functions. Zonal average diabatic forcing is also applied. When the eddy flux parametrizations act on the zonal fields only, realistic steady states are obtained if a coarse meridional truncation is applied, but explicit baroclinic instability occurs if higher meridional modes are included. Explicit baroclinic instability is suppressed if the parametrizations act also on the long wave fields; and in this case it is found that diabatic forcing of the largest scales of motion is the most important generator of stationary long waves in the model. Various reformulations are considered, and the problem of devizing better transient eddy parametrizations is discussed. INTRODUCTIONOne of the main objectives of climate research is the construction of reliable numerical models of the global atmospheric circulation. Most of the activity in this field is at present being channelled into the development of general circulation models which attempt to resolve the transient large-scale eddies in sufficient detail (both temporally and spatially) to reproduce their transfer properties adequately.Parametrized models, in which the transfers carried out by the transient large-scale eddies are represented in terms of the mean fields, are less developed, and nearly all deal explicitly with the zonal average fields only, (For reviews, see Schneider and Dickinson (1974), and GARP (1975).) These zonal average models are extremely useful in the development of rational theories of the general circulation, and for testing parametrization schemes (see, for example, White and Green (1982)) but it is difficult to represent in such formulations the effects of the quasi-stationary zonal asymmetries which arise in the real atmosphere because of the distribution of thermal properties and the elevation of the continents. In any case, to rival the general circulation models, parametrized models should surely attempt to reproduce the three-dimensional time-averaged circulation, and not just the zonal average fields.In this paper we explore the possibility of using a three-dimensional time-dependent model to represent the largest scales of atmospheric motion, whilst applying parametric expressions to represent the effects of all smaller scales. The explicit part of the model is composed of the zonal average fields and the first three zonal wavenumbers. We imagine the zonally asymmetric part of the model to represent the slowly-evolving long wave pattern which dominates the circulation averaged over periods of a month or more (Eliasen and Machenhauer 1965;Blackmon 1976) and w...

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Anelastic and Compressible Simulation of Moist Dynamics at Planetary Scales

Kurowski

Grabowski

Smolarkiewicz

2015

Journal of the Atmospheric Sciences

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Moist anelastic and compressible numerical solutions to the planetary baroclinic instability and climate benchmarks are compared. The solutions are obtained by applying a consistent numerical framework for discrete integrations of the various nonhydrostatic flow equations. Moist extension of the baroclinic instability benchmark is formulated as an analog of the dry case. Flow patterns, surface vertical vorticity and pressure, total kinetic energy, power spectra, and total amount of condensed water are analyzed. The climate benchmark extends the baroclinic instability study by addressing long-term statistics of an idealized planetary equilibrium and associated meridional transports. Short-term deterministic anelastic and compressible solutions differ significantly. In particular, anelastic baroclinic eddies propagate faster and develop slower owing to, respectively, modified dispersion relation and abbreviated baroclinic vorticity production. These eddies also carry less kinetic energy, and the onset of their rapid growth occurs later than for the compressible solutions. The observed differences between the two solutions are sensitive to initial conditions as they diminish for large-amplitude excitations of the instability. In particular, on the climatic time scales, the anelastic and compressible solutions evince similar zonally averaged flow patterns with the matching meridional transports of entropy, momentum, and moisture.

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General circulation of the atmosphere

Cited by 3 publications

References 311 publications

Role of Microphysics and Convective Autoconversion for the Better Simulation of Tropical Intraseasonal Oscillations (MISO and MJO)

Role of Microphysics and Convective Autoconversion for the Better Simulation of Tropical Intraseasonal Oscillations (MISO and MJO)

A non‐linear atmospheric long wave model incorporating parametrizations of transient baroclinic eddies

Anelastic and Compressible Simulation of Moist Dynamics at Planetary Scales

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