AUTHOR=Kattel Dambaru Ballab , Salih Haitham Aabdin Mohamed , Yao Tandong , Ullah Kalim 

TITLE=Near-Surface Air Temperature Dependence on Elevation and Geographical Coordinates Over Tropical Desert Land Surfaces

JOURNAL=Frontiers in Earth Science

VOLUME=9

YEAR=2022

URL=https://www.frontiersin.org/journals/earth-science/articles/10.3389/feart.2021.777381

DOI=10.3389/feart.2021.777381

ISSN=2296-6463

ABSTRACT=<p>This study examined 30-year of <italic>in situ</italic> observations (1981–2010) to determine monthly, and diurnal characteristics of near-surface temperature gradients (TG) in the Sudanese desert, both spatially and with elevation. The TG variation, along with its spatial and elevation dependence, forcing mechanisms for its variability, and its relationship with moisture and gradients of other climatic variables, were evaluated using a multi-collinearity approach and empirical analysis, respectively. A distinct annual cycle was observed in both the temperature gradient (or lapse rate) with elevation (TG<sub>E</sub>) and the temperature gradient with latitude (TG<sub>Lat</sub>). The TG<sub>E</sub> is strongly negative during the warmer months (summer) and less strongly negative (or even positive) during the colder months (winter). However, for TG<sub>Lat,</sub> the results are reversed. The mean TG<sub>E</sub> value steepens during the summer due to intense adiabatic cooling during the day and less inversion during the night, while this process is reversed for the observed shallower TG<sub>Lat</sub> value in the same season. This result is attributed to desert characteristics at the northern lower elevations or higher latitudes, as well as the effects of the ITCZ, moisture, and cloud cover as a result of high elevations at lower latitudes in the south and southwest region. Low solar insolation, and Mediterranean cold airflow and littoral effect, combined with inversion and radiative cooling at lower elevations or northern higher latitudes, lead the TG<sub>E</sub> (TG<sub>Lat</sub>) value to be shallow (steep) during the drier months. Excluding the inversion and radiative cooling at night, this effect is more pronounced in the winter. The extreme high and low values of TG<sub>E</sub> and TG<sub>Lat</sub>, as well as their diurnal range, were found to strongly coincide with variations in the equatorial trough, as well as diurnal radiative energy differences and the regional synoptic phenomenon. In addition to being valuable for hydro-climatic, ecological, and agricultural modeling, this study can be replicated in other tropical desert areas around the world to gain a better understanding of desert’s climate.</p>