I. L. Karol scite author profile

The chemistry-climate model (CCM) SOCOL has been used to evaluate the contributions of the main anthropogenic factors to the simulated changes of ozone and stratospheric dynamics during the 21st century. As the main anthropogenic factors we consider the atmospheric concentration of the greenhouse gases (GHG), ozone depleting substances (ODS) and sea surface temperature and sea ice (SST/SI). The latter is considered here as an independent factor because the majority of the CCMs prescribe its evolution. We have performed three sets of "time slice" numerical experiments for the years 2000, 2050, and 2100 taking into account all factors separately and all together. The total column ozone increase during the first half of the 21st century is caused by the ODS, especially in the middle and high latitudes of both hemispheres. In the tropics and the extra tropical region of the Northern Hemisphere (NH) the SST/SI forcing plays a very important role in the evolution of atmospheric ozone during the second half of the 21st century. The GHG affect the temperature and ozone mainly in the upper stratosphere and in the lower stratosphere of the high latitudes of the Southern Hemisphere (SH). In the lower tropical stratosphere of the NH, the long-term changes of the temperature, zonal wind and the meridional circulation are controlled mainly by the SST/SI. The strong contribution of the SST/SI to the ozone and circulation changes in the future implies that some differences between the results by different CCMs could be caused by the applied SST/SI rather than by the CCM's deficiencies. We suggest taking this issue into account for the planning of the future model evaluation campaigns

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Assessment of the effect of the Montreal Protocol on atmospheric ozone

Egorova

Rozanov

Schlesinger

et al. 2001

Geophysical Research Letters

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Is aerosol scattering in the stratosphere a safety technology preventing global warming?

Meleshko

Kattsov

Karol

2010

Russ. Meteorol. Hydrol.

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In accordance with numerous investigations, global climate warming due to the increased greenhouse gas content in the atmosphere can significantly influence the environment already in the near decades. In order to mitigate or prevent possible adverse consequences of this warming the technologies on reducing greenhouse gas emissions as well as a deliberate interference with climate, including its control, are under consideration. Let us analyze the present investigations on the estimate of the influence of a simultaneous increase in the atmospheric CO 2 concentration and in the stratospheric aerosol on the global and regional climate, ozone layer, and World Ocean acidification. It is noted that the production and subsequent maintenance of the artificial aerosol layer in the stratosphere could, in principle, eliminate or retard climate warming, but it would be accompanied by a decrease in the global precipitation, especially in the tropical zone. Furthermore, the stratospheric aerosol screen does not solve the problem of the atmospheric CO 2 increase, which in turn results in the further World Ocean acidification, and thus has an adverse effect on the marine part of the biosphere. Political and ethic issues connected with the deliberate global man interference with the natural environment are also under considerations.

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Reconstruction of the methane fluxes from the west Siberia gas fields by the 3D regional chemical transport model

Jagovkina

Karol

Zubov

et al. 2000

Atmospheric Environment

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Quantitative investigation of stratospheric mixing processes by means of long lived radon decay products

Karol

1966

TELLUSA

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A model of tracer transport process in the meridional plane of lower stratosphere is briefly outlined and the corresponding partial differential equation for tracer concentration is deduced. For the long lived radon daughters RaD(PbalO) and RaF(PoZ1O) in the Northern Hemisphere stratosphere such equations can be simplified to one dimensional stationary form, describing the quasivertical transport of these isotopes.The mean values of quasivertical velocity and turbulent diffusion coefficient in the lower stratosphere of different latitudes of Northern Hemisphere are estimated by comparison of last equation solutions with the published results of aircraft measurements of RaD and RaF concentration in 1961 and 1962. These estimated values agree with the known qualitative ideas on latitudinal and seasonal changes of the stratospheric mixing intensity.

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I. L. Karol

Role of external factors in the evolution of the ozone layer and stratospheric circulation in 21st century

Assessment of the effect of the Montreal Protocol on atmospheric ozone

Is aerosol scattering in the stratosphere a safety technology preventing global warming?

Reconstruction of the methane fluxes from the west Siberia gas fields by the 3D regional chemical transport model

Quantitative investigation of stratospheric mixing processes by means of long lived radon decay products

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