Abstract
Abstract. Despite turbulence being a fundamental transport process in the boundary layer, the capability of current numerical models to represent it is undermined by the limits of the adopted assumptions, notably that of local equilibrium. Here we leverage the potential of extensive observations in determining the variability in turbulence dissipation rate (ϵ). These observations can provide insights towards the understanding of the scales at which the major assumption of local equilibrium between generation and dissipation of turbulence is invalid. Typically, observations of ϵ require time- and labor-intensive measurements from sonic and/or hot-wire anemometers. We explore the capability of wind Doppler lidars to provide measurements of ϵ. We refine and extend an existing method to accommodate different atmospheric stability conditions. To validate our approach, we estimate ϵ from four wind Doppler lidars during the 3-month XPIA campaign at the Boulder Atmospheric Observatory (Colorado), and we assess the uncertainty of the proposed method by data intercomparison with sonic anemometer measurements of ϵ. Our analysis of this extensive dataset provides understanding of the climatology of turbulence dissipation over the course of the campaign. Further, the variability in ϵ with atmospheric stability, height, and wind speed is also assessed. Finally, we present how ϵ increases as nocturnal turbulence is generated during low-level jet events.
Highlights
Turbulence within the atmospheric boundary layer is critically important to transfer heat, momentum and moisture between the surface and the upper atmosphere (Sobel and Neelin, 2006)
The turbulence generated by the strong wind acceleration during nocturnal low-level jets can deeply modify the daytime climatology of Turbulence parametrizations currently used in numerical models have been proven (Yang et al, 2017) to have considerable limitations which undermine the quality of representations of processes in the atmospheric boundary layer
Most mesoscale planetary boundary layer models make the assumption of local equilibrium between production and dissipation of turbulence
Summary
Turbulence within the atmospheric boundary layer is critically important to transfer heat, momentum and moisture between the surface and the upper atmosphere (Sobel and Neelin, 2006). Global and regional models need an accurate representation of turbulence to produce precise atmospheric predictions of winds, temperature and moisture in the boundary layer. We estimate turbulence dissipation rate from the 3-month period of the Experimental Planetary Boundary Layer Instrumentation Assessment (XPIA) field campaign (Lundquist et al, 2017), described, from sonic anemometers and vertical profiling lidars, with the approach summarized in Sect. To analyze the variability in turbulence dissipation rate, we use data from the meteorological tower and wind Doppler lidars deployed during the XPIA field campaign, summarized in Lundquist et al (2017). Grass and low-crop fields surround the observatory, with some scattered trees and compact buildings
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