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Chemistry-climate model SOCOL : a validation of the present-day climatology. / Rozanov, E; Manzini, E; Schmutz, W; Peter, T; Зубов, Владимир Аркадьевич; Egorova, Tatiana.

In: Atmospheric Chemistry and Physics, Vol. 5, 21.06.2005, p. 1557-1576.

Research output: Contribution to journalArticlepeer-review

Harvard

Rozanov, E, Manzini, E, Schmutz, W, Peter, T, Зубов, ВА & Egorova, T 2005, 'Chemistry-climate model SOCOL: a validation of the present-day climatology', Atmospheric Chemistry and Physics, vol. 5, pp. 1557-1576. https://doi.org/10.5194/acp-5-1557-2005

APA

Rozanov, E., Manzini, E., Schmutz, W., Peter, T., Зубов, В. А., & Egorova, T. (2005). Chemistry-climate model SOCOL: a validation of the present-day climatology. Atmospheric Chemistry and Physics, 5, 1557-1576. https://doi.org/10.5194/acp-5-1557-2005

Vancouver

Rozanov E, Manzini E, Schmutz W, Peter T, Зубов ВА, Egorova T. Chemistry-climate model SOCOL: a validation of the present-day climatology. Atmospheric Chemistry and Physics. 2005 Jun 21;5:1557-1576. https://doi.org/10.5194/acp-5-1557-2005

Author

Rozanov, E ; Manzini, E ; Schmutz, W ; Peter, T ; Зубов, Владимир Аркадьевич ; Egorova, Tatiana. / Chemistry-climate model SOCOL : a validation of the present-day climatology. In: Atmospheric Chemistry and Physics. 2005 ; Vol. 5. pp. 1557-1576.

BibTeX

@article{e36cf83411bc41d3ae652f917afef7ae,
title = "Chemistry-climate model SOCOL: a validation of the present-day climatology",
abstract = "In this paper we document {"}SOCOL{"}, a new chemistry-climate model, which has been ported for regular PCs and shows good wall-clock performance. An extensive validation of the model results against present-day climate data obtained from observations and assimilation data sets shows that the model describes the climatological state of the atmosphere for the late 1990s with reasonable accuracy. The model has a significant temperature bias only in the upper stratosphere and near the tropopause at high latitudes. The latter is the result of the rather low vertical resolution of the model near the tropopause. The former can be attributed to a crude representation of radiation heating in the middle atmosphere. A comparison of the simulated and observed link between the tropical stratospheric structure and the strength of the polar vortex shows that in general, both observations and simulations reveal a higher temperature and ozone mixing ratio in the lower tropical stratosphere for the case with stronger Polar night jet (PNJ) and slower Brewer-Dobson circulation as predicted by theoretical studies.",
keywords = "DOPPLER-SPREAD PARAMETERIZATION, GENERAL-CIRCULATION MODEL, CHEMICAL-TRANSPORT MODEL, WAVE MOMENTUM DEPOSITION, MIDDLE ATMOSPHERE, OZONE, GCM, PHOTOCHEMISTRY, STRATOSPHERE, OSCILLATION",
author = "E Rozanov and E Manzini and W Schmutz and T Peter and Зубов, {Владимир Аркадьевич} and Tatiana Egorova",
year = "2005",
month = jun,
day = "21",
doi = "10.5194/acp-5-1557-2005",
language = "Английский",
volume = "5",
pages = "1557--1576",
journal = "Atmospheric Chemistry and Physics",
issn = "1680-7316",
publisher = "Copernicus GmbH ",

}

RIS

TY - JOUR

T1 - Chemistry-climate model SOCOL

T2 - a validation of the present-day climatology

AU - Rozanov, E

AU - Manzini, E

AU - Schmutz, W

AU - Peter, T

AU - Зубов, Владимир Аркадьевич

AU - Egorova, Tatiana

PY - 2005/6/21

Y1 - 2005/6/21

N2 - In this paper we document "SOCOL", a new chemistry-climate model, which has been ported for regular PCs and shows good wall-clock performance. An extensive validation of the model results against present-day climate data obtained from observations and assimilation data sets shows that the model describes the climatological state of the atmosphere for the late 1990s with reasonable accuracy. The model has a significant temperature bias only in the upper stratosphere and near the tropopause at high latitudes. The latter is the result of the rather low vertical resolution of the model near the tropopause. The former can be attributed to a crude representation of radiation heating in the middle atmosphere. A comparison of the simulated and observed link between the tropical stratospheric structure and the strength of the polar vortex shows that in general, both observations and simulations reveal a higher temperature and ozone mixing ratio in the lower tropical stratosphere for the case with stronger Polar night jet (PNJ) and slower Brewer-Dobson circulation as predicted by theoretical studies.

AB - In this paper we document "SOCOL", a new chemistry-climate model, which has been ported for regular PCs and shows good wall-clock performance. An extensive validation of the model results against present-day climate data obtained from observations and assimilation data sets shows that the model describes the climatological state of the atmosphere for the late 1990s with reasonable accuracy. The model has a significant temperature bias only in the upper stratosphere and near the tropopause at high latitudes. The latter is the result of the rather low vertical resolution of the model near the tropopause. The former can be attributed to a crude representation of radiation heating in the middle atmosphere. A comparison of the simulated and observed link between the tropical stratospheric structure and the strength of the polar vortex shows that in general, both observations and simulations reveal a higher temperature and ozone mixing ratio in the lower tropical stratosphere for the case with stronger Polar night jet (PNJ) and slower Brewer-Dobson circulation as predicted by theoretical studies.

KW - DOPPLER-SPREAD PARAMETERIZATION

KW - GENERAL-CIRCULATION MODEL

KW - CHEMICAL-TRANSPORT MODEL

KW - WAVE MOMENTUM DEPOSITION

KW - MIDDLE ATMOSPHERE

KW - OZONE

KW - GCM

KW - PHOTOCHEMISTRY

KW - STRATOSPHERE

KW - OSCILLATION

U2 - 10.5194/acp-5-1557-2005

DO - 10.5194/acp-5-1557-2005

M3 - статья

VL - 5

SP - 1557

EP - 1576

JO - Atmospheric Chemistry and Physics

JF - Atmospheric Chemistry and Physics

SN - 1680-7316

ER -

ID: 121595233