Abstract

We currently have a limited understanding of the spatial and temporal variability in vertically stratified atmospheric layers over Namibia and the southeast Atlantic (SEA) Ocean. Stratified layers are relevant to the transport and dilution of local and long-range transported atmospheric constituents. This study used eleven years of global positioning system radio occultation (GPS-RO) signal refractivity data (2007–2017) over Namibia and the adjacent ocean surfaces, and three years of radiosonde data from Walvis Bay, Namibia, to study the character and variability in stratified layers. From the GPS-RO data and up to a height of 10 km, we studied the spatial and temporal variability in the point of minimum gradient in refractivity, and the temperature inversion height, depth and strength. We also present the temporal variability of temperature inversions and the boundary layer height (BLH) from radiosondes. The BLH was estimated by the parcel method, the top of a surface-based inversion, the top of a stable layer identified by the bulk Richardson number (RN), and the point of minimum gradient in the refractivity (for comparison with GPS-RO data). A comparison between co-located GPS-RO to radiosonde temperature profiles found good agreement between the two, and an average underestimation of GPS-RO to radiosonde temperatures of −0.45 ± 1.25 °C, with smaller differences further from the surface and with decreasing atmospheric moisture content. The minimum gradient (MG) of refractivity, calculated from these two datasets were generally in good agreement (230 ± 180 m), with an exeption of a few cases when differences exceeded 1000 m. The surface of MG across the region of interest was largely affected by macroscale circulation and changes in atmospheric moisture and cloud, and was not consistent with BLH(RN). We found correlations in the character of low-level inversions with macroscale circulation, radiation interactions with the surface, cloud cover over the ocean and the seasonal maximum in biomass burning over southern Africa. Radiative cooling on diurnal scales also affected elevated inversions between 2.5 and 10 km, with more co-occurring inversions observed at night and in the morning. Elevated inversions formed most frequently over the subcontinent and under subsidence by high-pressure systems in the colder months. Despite this macroscale influence peaking in the winter, the springtime inversions, like those at low levels, were strongest.

Highlights

  • Southern Africa is positioned in the tropics and middle latitudes where atmospheric circulation is primarily affected by the high-pressure belt under the descending limb of the Hadley cell (Tyson and Preston-Whyte, 2014)

  • The boundary layer height (BLH) was estimated by the parcel method, the top of a surface-based inversion, the top of a stable layer identified by the bulk Richardson number (RN), and the point of minimum gradient in the refractivity

  • This paper presents the results of the diurnal and seasonal variability of the boundary layer height (BLH) obtained by the analysis of 3 years of radiosonde data launched by the Namibia Meteorology Service from Walvis Bay airport (22°58'43.5"S 14°38'28.4"E, 97 m above mean sea level), within the coastal margin of Namibia

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Summary

Introduction

Southern Africa is positioned in the tropics and middle latitudes where atmospheric circulation is primarily affected by the high-pressure belt under the descending limb of the Hadley cell (Tyson and Preston-Whyte, 2014). The 850 hPa stability structure only formed below the elevation of the continental plateau up to the great escarpment (up to 1000 m above sea level) These studies made use of traditional radiosondes released daily or more frequently during short-term intensive field campaigns, resulting in a lack of spatial and temporal data coverage. We present the first observational study of atmospheric discontinuities over Namibia and the SEA based on global positioning system radio occultation (GPS-RO) data from the Constellation Observing System for Meteorology, Ionosphere, and Climate (COSMIC) spaceborne mission data collected between 2007 and 2017 These observations provide a statistical view of the spatial and temporal variability of atmospheric discontinuities, such as temperature inversions. Region of investigation the east), separated base on a priori information about variability in atmospheric stratification over similar coastal regions

COSMIC GPS-RO
Radiosondes
Point of minimum gradient in refractivity and vapour pressure
Calculation of boundary layer height from radiosonde data
Subsidence inversions
Temperature
Minimum gradient of refractivity
Boundary layer height
Temperature inversions
Co-occurring inversions
Macroscale circulation
Differential heating
Cloud fraction
Biomass burning aerosols
Findings
Conclusions
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