Abstract
Abstract. Planetary boundary layer (PBL) processes are important for weather, climate, and tracer transport and concentration. One measure of the strength of these processes is the PBL depth. However, no single PBL depth definition exists and several studies have found that the estimated depth can vary substantially based on the definition used. In the Goddard Earth Observing System (GEOS-5) atmospheric general circulation model, the PBL depth is particularly important because it is used to calculate the turbulent length scale that is used in the estimation of turbulent mixing. This study analyzes the impact of using three different PBL depth definitions in this calculation. Two definitions are based on the scalar eddy diffusion coefficient and the third is based on the bulk Richardson number. Over land, the bulk Richardson number definition estimates shallower nocturnal PBLs than the other estimates while over water this definition generally produces deeper PBLs. The near-surface wind velocity, temperature, and specific humidity responses to the change in turbulence are spatially and temporally heterogeneous, resulting in changes to tracer transport and concentrations. Near-surface wind speed increases in the bulk Richardson number experiment cause Saharan dust increases on the order of 1 × 10−4 kg m−2 downwind over the Atlantic Ocean. Carbon monoxide (CO) surface concentrations are modified over Africa during boreal summer, producing differences on the order of 20 ppb, due to the model's treatment of emissions from biomass burning. While differences in carbon dioxide (CO2) are small in the time mean, instantaneous differences are on the order of 10 ppm and these are especially prevalent at high latitude during boreal winter. Understanding the sensitivity of trace gas and aerosol concentration estimates to PBL depth is important for studies seeking to calculate surface fluxes based on near-surface concentrations and for studies projecting future concentrations.
Highlights
Aerosols exert control over the Earth’s climate in several different ways
Using the Goddard Earth Observing System (GEOS-5) model, McGrathSpangler and Molod (2014) evaluated seven planetary boundary layer (PBL) depth definitions and found that the largest variations in depth occur for the nocturnal boundary layer and that the PBL depth estimated with Richardson-number-based methods are lower than PBL depths estimated using methods based on the eddy diffusion coefficient
The present analysis examines the impact of three of those PBL depth definitions on tracer transport through their use in calculating the turbulent length scale
Summary
Aerosols exert control over the Earth’s climate in several different ways. Directly, they affect the radiative budget through absorption and scattering of both shortwave and long-wave radiation (Sokolik and Toon, 1996; Balkanski et al, 2007). Using the Goddard Earth Observing System (GEOS-5) model, McGrathSpangler and Molod (2014) evaluated seven PBL depth definitions and found that the largest variations in depth occur for the nocturnal boundary layer and that the PBL depth estimated with Richardson-number-based methods are lower than PBL depths estimated using methods based on the eddy diffusion coefficient They found that Richardsonnumber-based methods produce a shallower midday PBL under warm, moist conditions, such as in the tropical rainforest. This study seeks to understand the effect of changing the PBL depth definition used within the GEOS-5 AGCM to estimate the turbulent length scale and the impact on the emission, loss, and transport processes of atmospheric trace gases and aerosols.
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