Title : ( Effects of atmospheric stability conditions on heat fluxes from small water surfaces in (semi-)arid regions )
Authors: Ali Abbasi , F. Ohene Annor , N. van de Giesen ,Abstract
Atmospheric stability conditions over the water surface can affect the evaporative and convective heat fluxes from the water surface. Atmospheric instability occurred 72.5% of the time and resulted in 44.7 and 89.2% increases in the average and maximum estimated evaporation, respectively, when compared to the neutral condition for a small shallow lake (Binaba) in Ghana. The proposed approach is based on the bulk-aerodynamic transfer method and the Monin-Obukhov similarity theory (MOST) using standard meteorological parameters measured over the surrounding land. For water surface temperature, a crucial parameter in heat flux estimation from water surfaces, an applicable method is proposed. This method was used to compute heat fluxes and compare them with observed heat fluxes. The heat flux model was validated using sensible heat fluxes measured with a 3-D sonic anemometer. The results show that an unstable atmospheric condition has a significant effect in enhancing evaporation alongside the sensible heat flux from water surfaces.
Keywords
, Evaporation, Small Reservoirs, Atmospheric Boundary Layer, Stability Condition, Semi-arid Region@article{paperid:1066340,
author = {Abbasi, Ali and F. Ohene Annor and N. Van De Giesen},
title = {Effects of atmospheric stability conditions on heat fluxes from small water surfaces in (semi-)arid regions},
journal = {Hydrological Sciences Journal},
year = {2017},
volume = {62},
number = {9},
month = {June},
issn = {0262-6667},
pages = {1422--1439},
numpages = {17},
keywords = {Evaporation; Small Reservoirs; Atmospheric Boundary Layer; Stability Condition; Semi-arid Region},
}
%0 Journal Article
%T Effects of atmospheric stability conditions on heat fluxes from small water surfaces in (semi-)arid regions
%A Abbasi, Ali
%A F. Ohene Annor
%A N. Van De Giesen
%J Hydrological Sciences Journal
%@ 0262-6667
%D 2017