A Method for Deriving the Boundary Layer Mixing Height from MODIS Atmospheric Profile Data

Abstract. Surface-based radon (222Rn) measurements can be combined with lidar backscatter to obtain a higher quality time series of mixing height within the Planetary Boundary-Layer (PBL) than is possible from lidar alone, and a more quantitative measure of mixing height than is possible from only radon. The lidar measurements benefit because even when aerosol layers are detected, reliably attributing the mixing height to the correct layer presents a challenge. By combining lidar with a mixing length scale derived from a time series of radon concentration, automated and robust attribution is possible during the morning transition. Radon measurements also provide mixing information during the night and with the addition of lidar these measurements become insensitive to night-to-night changes in radon emissions. After calibration with lidar, the radon-derived equivalent mixing height agrees with other measures of mixing on daily and hourly time scales and is a potential method for studying intermittent mixing in nocturnal boundary layers.

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Mean and Turbulent Velocity Profile Measurements on the Suction Side of a Film Cooled Turbine Vane

Volume 3B: Heat Transfer ◽

10.1115/gt2013-94931 ◽

2013 ◽

Author(s):

John W. McClintic ◽

Thomas E. Dyson ◽

David G. Bogard ◽

Sean D. Bradshaw

Keyword(s):

Boundary Layer ◽

Velocity Profile ◽

Film Cooling ◽

Large Scale ◽

Suction Side ◽

Profile Data ◽

Downstream Location ◽

Film Cooling Effectiveness ◽

Turbine Vane ◽

Layer Velocity

Boundary layer velocity and turbulence profiles were measured on the suction side of a scaled up, film-cooled turbine vane airfoil. There have been a number of previous studies of the velocity profile on a turbine vane, but few have taken velocity profile data with film cooling, and none have taken such data on the suction side of the vane. Velocity and turbulence profile data were taken at two locations on the suction side of the vane — one at a high curvature region and one further downstream in a low curvature region. Data were collected for high (20%) and low (0.5%) mainstream turbulence conditions. For the upstream, high curvature location, velocity and turbulence profiles were found with and without the showerhead blowing and within and outside of the merged showerhead coolant jet. The data for the low curvature, downstream location was taken with injection from the showerhead alone, a second upstream row of holes alone, and the combination of the two cases. It was found that the presence of an active upstream row of holes thickens the boundary layer and increases urms both within and beyond the extent of the boundary layer. Span-wise variations showed that these effects are strongest within the core of the coolant jets. At the downstream location, the boundary layer velocity profile was most strongly influenced by the row of holes immediately upstream of that location. Finally, turbulence integral length scale data showed the effect of large scale mainstream turbulence penetrating the boundary layer. The increase in turbulence, thickening of the boundary layer, and large scale turbulence all play important roles in row to row coolant interactions and affect the film cooling effectiveness.

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Exploring fractal features in the mixing height zone of planetary boundary layer from observed sodar data

Remote Sensing Letters ◽

10.1080/2150704x.2014.970715 ◽

2014 ◽

Vol 5 (9) ◽

pp. 823-832 ◽

Cited By ~ 1

Author(s):

Sreemoyee Roy ◽

Abhik Mukherjee

Keyword(s):

Boundary Layer ◽

Planetary Boundary Layer ◽

Mixing Height ◽

Sodar Data

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Doppler Lidar Estimation of Mixing Height Using Turbulence, Shear, and Aerosol Profiles

Journal of Atmospheric and Oceanic Technology ◽

10.1175/2008jtecha1157.1 ◽

2009 ◽

Vol 26 (4) ◽

pp. 673-688 ◽

Cited By ~ 110

Author(s):

Sara C. Tucker ◽

Christoph J. Senff ◽

Ann M. Weickmann ◽

W. Alan Brewer ◽

Robert M. Banta ◽

...

Keyword(s):

Boundary Layer ◽

Air Quality ◽

Potential Temperature ◽

Lidar Data ◽

Doppler Lidar ◽

Mixing Height ◽

Coherent Doppler Lidar ◽

Lidar Measurements ◽

Comparison Of The Results ◽

Humidity Profiles

Abstract The concept of boundary layer mixing height for meteorology and air quality applications using lidar data is reviewed, and new algorithms for estimation of mixing heights from various types of lower-tropospheric coherent Doppler lidar measurements are presented. Velocity variance profiles derived from Doppler lidar data demonstrate direct application to mixing height estimation, while other types of lidar profiles demonstrate relationships to the variance profiles and thus may also be used in the mixing height estimate. The algorithms are applied to ship-based, high-resolution Doppler lidar (HRDL) velocity and backscattered-signal measurements acquired on the R/V Ronald H. Brown during Texas Air Quality Study (TexAQS) 2006 to demonstrate the method and to produce mixing height estimates for that experiment. These combinations of Doppler lidar–derived velocity measurements have not previously been applied to analysis of boundary layer mixing height—over the water or elsewhere. A comparison of the results to those derived from ship-launched, balloon-radiosonde potential temperature and relative humidity profiles is presented.

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A Three-Step Method for Estimating the Mixing Height Using Ceilometer Data from the Helsinki Testbed

Journal of Applied Meteorology and Climatology ◽

10.1175/jamc-d-12-058.1 ◽

2012 ◽

Vol 51 (12) ◽

pp. 2172-2187 ◽

Cited By ~ 25

Author(s):

Noora Eresmaa ◽

Jari Härkönen ◽

Sylvain M. Joffre ◽

David M. Schultz ◽

Ari Karppinen ◽

...

Keyword(s):

Boundary Layer ◽

Vertical Profile ◽

The Other ◽

Vertical Profiles ◽

Backscattering Coefficient ◽

Mixing Height ◽

Step Method ◽

Profile Method ◽

One Step ◽

The One

AbstractA new three-step idealized-profile method to estimate the mixing height from vertical profiles of ceilometer backscattering coefficient is developed to address the weaknesses found with such estimates that are based on the one-step idealized-profile method. This three-step idealized-profile method fits the backscattering coefficient profile of ceilometer measurements into an idealized scaled vertical profile of three error functions, thus having the potential to determine three aerosol layers (one for the surface layer, one for the mixing height, and one for the artificial layer caused by the weakened signal). This three-step idealized-profile method is tested with ceilometer and radiosounding data collected during the Helsinki Testbed campaign (2 January 2006–13 March 2007). Excluding cases with low aerosol concentration in the boundary layer, cases with clouds present, and cases with precipitation present, the resulting dataset consists of 97 simultaneous backscattering coefficient profiles and radiosoundings. The three-step method is compared with the one-step method and other commonly employed algorithms. A strong correlation (correlation coefficient r = 0.91) between the mixing heights as determined by the three-step method using ceilometer data and those determined from radiosoundings is an improvement over the same correlation using the one-step method (r = 0.28), as well as the other algorithms.

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Parameterization of vertical diffusion and the atmospheric boundary layer height determination in the EMEP model

Atmospheric Chemistry and Physics ◽

10.5194/acp-10-341-2010 ◽

2010 ◽

Vol 10 (2) ◽

pp. 341-364 ◽

Cited By ~ 26

Author(s):

A. Jeričević ◽

L. Kraljević ◽

B. Grisogono ◽

H. Fagerli ◽

Ž. Večenaj

Keyword(s):

Boundary Layer ◽

Air Pollution ◽

Atmospheric Boundary Layer ◽

Model Development ◽

Monitoring And Evaluation ◽

Eddy Diffusivity ◽

Mixing Height ◽

Vertical Diffusion ◽

Height Determination ◽

Stable Conditions

Abstract. This paper introduces two changes of the turbulence parameterization for the EMEP (European Monitoring and Evaluation Programme) Eulerian air pollution model: the replacement of the Blackadar in stable and O'Brien in unstable turbulence formulations with an analytical vertical diffusion profile (K(z)) called Grisogono, and a different mixing height determination, based on a bulk Richardson number formulation (RiB). The operational or standard (STD) and proposed new parameterization for eddy diffusivity have been validated in all stability conditions against the observed daily surface nitrogen dioxide (NO2), sulphur dioxide (SO2) and sulphate (SO42−) concentrations at different EMEP stations during the year 2001. A moderate improvement in the correlation coefficient and bias for NO2 and SO2 and a slight improvement for sulphate is found for the most of the analyzed stations with the Grisogono K(z) scheme, which is recommended for further application due to its scientific and technical advantages. The newly extended approach for the mechanical eddy diffusivity is applied to the Large Eddy Simulation data focusing at the bulk properties of the neutral and stable atmospheric boundary layer. A summary and extension of the previous work on the empirical coefficients in neutral and stable conditions is provided with the recommendations to the further model development. Special emphasis is given to the representation of the ABL in order to capture the vertical transport and dispersion of the atmospheric air pollution. Two different schemes for the ABL height determination are evaluated against the radiosounding data in January and July 2001, and against the data from the Cabauw tower, the Netherlands, for the same year. The validation of the ABL parameterizations has shown that the EMEP model is able to reproduce spatial and temporal mixing height variability. Improvements are identified especially in stable conditions with the new ABL height scheme based on the RiB number.

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Sensitivity of Landsat 8 Surface Temperature Estimates to Atmospheric Profile Data: A Study Using MODTRAN in Dryland Irrigated Systems

Remote Sensing ◽

10.3390/rs9100988 ◽

2017 ◽

Vol 9 (10) ◽

pp. 988 ◽

Cited By ~ 14

Author(s):

◽

Keyword(s):

Surface Temperature ◽

Landsat 8 ◽

Profile Data ◽

Atmospheric Profile

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Temperature gradient method for deriving planetary boundary layer height from AIRS profile data over the Heihe River Basin of China

Arabian Journal of Geosciences ◽

10.1007/s12517-020-06357-9 ◽

2021 ◽

Vol 14 (2) ◽

Author(s):

Xueliang Feng ◽

Le Tang ◽

Gang Han ◽

Wenshuang Chen

Keyword(s):

Boundary Layer ◽

Temperature Gradient ◽

Gradient Method ◽

Heihe River ◽

Planetary Boundary Layer Height ◽

Profile Data ◽

Layer Height ◽

Boundary Layer Height ◽

Temperature Gradient Method ◽

The Heihe River Basin

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Boundary layer dynamics over London, UK, as observed using Doppler lidar during REPARTEE-II

Atmospheric Chemistry and Physics ◽

10.5194/acp-11-2111-2011 ◽

2011 ◽

Vol 11 (5) ◽

pp. 2111-2125 ◽

Cited By ~ 96

Author(s):

J. F. Barlow ◽

T. M. Dunbar ◽

E. G. Nemitz ◽

C. R. Wood ◽

M. W. Gallagher ◽

...

Keyword(s):

Boundary Layer ◽

Turbulent Mixing ◽

Sampling Rate ◽

Sonic Anemometer ◽

Aerosol Layer ◽

Doppler Lidar ◽

Mixing Height ◽

Data Set ◽

Layer Height ◽

Lidar Observations

Abstract. Urban boundary layers (UBLs) can be highly complex due to the heterogeneous roughness and heating of the surface, particularly at night. Due to a general lack of observations, it is not clear whether canonical models of boundary layer mixing are appropriate in modelling air quality in urban areas. This paper reports Doppler lidar observations of turbulence profiles in the centre of London, UK, as part of the second REPARTEE campaign in autumn 2007. Lidar-measured standard deviation of vertical velocity averaged over 30 min intervals generally compared well with in situ sonic anemometer measurements at 190 m on the BT telecommunications Tower. During calm, nocturnal periods, the lidar underestimated turbulent mixing due mainly to limited sampling rate. Mixing height derived from the turbulence, and aerosol layer height from the backscatter profiles, showed similar diurnal cycles ranging from c. 300 to 800 m, increasing to c. 200 to 850 m under clear skies. The aerosol layer height was sometimes significantly different to the mixing height, particularly at night under clear skies. For convective and neutral cases, the scaled turbulence profiles resembled canonical results; this was less clear for the stable case. Lidar observations clearly showed enhanced mixing beneath stratocumulus clouds reaching down on occasion to approximately half daytime boundary layer depth. On one occasion the nocturnal turbulent structure was consistent with a nocturnal jet, suggesting a stable layer. Given the general agreement between observations and canonical turbulence profiles, mixing timescales were calculated for passive scalars released at street level to reach the BT Tower using existing models of turbulent mixing. It was estimated to take c. 10 min to diffuse up to 190 m, rising to between 20 and 50 min at night, depending on stability. Determination of mixing timescales is important when comparing to physico-chemical processes acting on pollutant species measured simultaneously at both the ground and at the BT Tower during the campaign. From the 3 week autumnal data-set there is evidence for occasional stable layers in central London, effectively decoupling surface emissions from air aloft.

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