Showing total 2 results

1. Phase Shift between Changes in Global Temperature and Atmospheric CO2 Content under External Emissions of Greenhouse Gases into the Atmosphere.

Author

Muryshev, K. E., Eliseev, A. V., Denisov, S. N., Mokhov, I. I., Arzhanov, M. M., and Timazhev, A. V.

Subjects

*GLOBAL temperature changes, *ATMOSPHERIC temperature, *ATMOSPHERIC methane, *GREENHOUSE gases, *RADIATIVE forcing, *ATMOSPHERE

Abstract

The phase shift between changes in the global surface temperature Tg and atmospheric CO2 content has been shown earlier not to characterize causal relationships in the Earth system in the general case. Specifically, the sign of this phase shift under nongreenhouse radiative forcing changes depends on the time scale of this forcing. This paper analyzes the phase shift between changes in the global surface temperature Tg and the atmospheric CO2 content under synchronous external emissions of carbon dioxide and methane into the atmosphere on the basis of numerical experiments with the IAP RAS climatic model and a conceptual climate model with carbon cycle. For a sufficiently large time scale of external forcing, the changes in lag relative to the corresponding changes in Tg. [ABSTRACT FROM AUTHOR]

Published

2019

2. Spatial dependence of diurnal temperature range trends on precipitation from 1950 to 2004.

Author

Liming Zhou, Aiguo Dai, Yongjiu Dai, Vose, Russell S., Cheng-Zhi Zou, Yuhong Tian, and Haishan Chen

Subjects

*GLOBAL temperature changes, *CLIMATE change, *CLIMATOLOGY, *GLOBAL warming, *RADIATIVE forcing, TEMPERATURE & the environment

Abstract

This paper analyzes the spatial dependence of annual diurnal temperature range (DTR) trends from 1950–2004 on the annual climatology of three variables: precipitation, cloud cover, and leaf area index (LAI), by classifying the global land into various climatic regions based on the climatological annual precipitation. The regional average trends for annual minimum temperature ( T min) and DTR exhibit significant spatial correlations with the climatological values of these three variables, while such correlation for annual maximum temperature ( T max) is very weak. In general, the magnitude of the downward trend of DTR and the warming trend of T min decreases with increasing precipitation amount, cloud cover, and LAI, i.e., with stronger DTR decreasing trends over drier regions. Such spatial dependence of T min and DTR trends on the climatological precipitation possibly reflects large-scale effects of increased global greenhouse gases and aerosols (and associated changes in cloudiness, soil moisture, and water vapor) during the later half of the twentieth century. [ABSTRACT FROM AUTHOR]

Published

2009