Evaluation of Mixing-Height Retrievals from Automatic Profiling Lidars and Ceilometers in View of Future Integrated Networks in Europe

Haeffelin, Martial; Angelini, F.; Morille, Yohann; Martucci, Giovanni; Frey, Steffen; Gobbi, Gian Paolo; Lolli, Simone; O’Dowd, Colin; Sauvage, Laurent; Xueref-Rémy, Irène; Wastine, B.; Feist, Dietrich G.

doi:10.1007/s10546-011-9643-z

Cited by 247 publications

(254 citation statements)

References 34 publications

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“…Lidar provides direct measurements of aerosol profiles within the ABL. Several methods, such as the threshold method, gradient method, and variance method, have been developed to determine BLH by using lidar backscatter measurements (Hooper and Eloranta, 1986;Flamant et al, 1997;Menut et al, 1999;Sicard et al, 2006;Lammert and Bösenberg, 2006;Martucci et al, 2007;Emeis et al, 2008;Jordan et al, 2010;Haeffelin et al, 2012). However, the detected aerosol layers are not always consistent with ABL thermodynamical structures because aerosol vertical structures are affected by other factors.…”

Section: T Luo Et Al: Lidar-based Remote Sensing Of Atmospheric Boumentioning

confidence: 99%

Lidar-based remote sensing of atmospheric boundary layer height over land and ocean

2014

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Abstract. Atmospheric boundary layer (ABL) processes are important in climate, weather and air quality. A better understanding of the structure and the behavior of the ABL is required for understanding and modeling of the chemistry and dynamics of the atmosphere on all scales. Based on the systematic variations of the ABL structures over different surfaces, different lidar-based methods were developed and evaluated to determine the boundary layer height and mixing layer height over land and ocean. With Atmospheric Radiation Measurement Program (ARM) Climate Research Facility (ACRF) micropulse lidar (MPL) and radiosonde measurements, diurnal and season cycles of atmospheric boundary layer depth and the ABL vertical structure over ocean and land are analyzed. The new methods are then applied to satellite lidar measurements. The aerosol-derived global marine boundary layer heights are evaluated with marine ABL stratiform cloud top heights and results show a good agreement between them.

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Section: T Luo Et Al: Lidar-based Remote Sensing Of Atmospheric Boumentioning

confidence: 99%

Lidar-based remote sensing of atmospheric boundary layer height over land and ocean

2014

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“…Of these steps, attribution poses the larger challenge (Haeffelin et al, 2012). Indeed the information available from an elastic-scattering lidar may be insufficient for successful attribution, so some schemes incorporate supplementary information, either from model output (Di Giuseppe et al, 2012) or additional sensors (Emeis et al, 2004).…”

Section: Published By Copernicus Publications On Behalf Of the Europementioning

confidence: 99%

“…Mixing heights were derived following a procedure based on the "STRAT-2D" method (Haeffelin et al, 2012). For each five minute block, S was averaged, and then the results arranged in a 2-D array as a function of time and range.…”

Section: Determining Mixing Height From Lidarmentioning

confidence: 99%

“…Under these conditions, collocating the lidar and radon detector might reduce, or remove, the observed lag between the two measurements. Furthermore, the seemingly incorrect attribution on 7 May could perhaps be rectified by using a more sophisticated merging algorithm, as might be achieved by applying the additional constraints described by Haeffelin et al (2012). Nevertheless, there will be days where the merging procedure fails or produces uncertain results.…”

Section: Using Radon To Improve Lidarmentioning

confidence: 99%

“…ceilometers) can also be used for determining mixing height (Münkel, 2007;Emeis et al, 2009Emeis et al, , 2012. Ceilometers have lower signal-to-noise ratios than lidars, which can make mixing height detection more difficult, but are less expensive to purchase and maintain and are becoming deployed more widely in growing networks (Haeffelin et al, 2012). The ongoing deployment of lidars, and ceilometers in particular, means there is potential to see meaningful outcomes from improvements to mixing height detection algorithms.…”

Section: Introductionmentioning

confidence: 99%

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Improved mixing height monitoring through a combination of lidar and radon measurements

et al. 2013

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Surface-based radon (<sup>222</sup>Rn) 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 reason why lidar measurements are improved is that there are times when lidar signals are ambiguous, and reliably attributing the mixing height to the correct aerosol 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. <br><br> Radon measurements provide mixing information during the night, but concentrations also depend on the strength of surface emissions. After processing radon in combination with lidar, we obtain nightly measurements of radon emissions and are able to normalise the mixing length scale for changing emissions. After calibration with lidar, the radon-derived equivalent mixing height agrees with other measures of mixing on daily and hourly timescales and is a potential method for studying intermittent mixing in nocturnal boundary layers

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Investigation of the atmospheric boundary layer depth variability and its impact on the ²²²Rn concentration at a rural site in France

et al. 2015

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Continuous monitoring of the atmospheric boundary layer (ABL) depth (z i ) is important for investigations of trace gases with near-surface sources. The aim of this study is to examine the temporal variability of z i on both diurnal and seasonal time scales over a full year (2011) and relate these changes to the atmospheric 222 Rn concentrations (C Rn ) measured near the top of a 200 m tower at a rural site (Trainou) in France. Continuous z i estimates were made using a combination of lidar and hourly four-height carbon dioxide (CO 2 ) profile measurements. Over the diurnal cycle, the 180 m C Rn reached a maximum in the late morning as the growing ABL passed through the inlet height (180 m) transporting upward high C Rn air from the nocturnal boundary layer. During late afternoon, a minimum in the C Rn occurred mainly due to ABL-mixing. We argue that ABL dilution occurs in two stages: first, during the rapid morning growth into the residual layer, and second, during afternoon with the free atmosphere when z i has reached its quasi-stationary height (around 750 m in winter or 1700 m in summer). An anticorrelation (R 2 of À0.49) was found while performing a linear regression analysis between the daily z i growth rates and the corresponding changes in the C Rn illustrating the ABL-dilution effect. We also analyzed the numerical proportions of the time within a season when z i remained lower than the inlet height and found a clear seasonal variability for the nighttime measurements with higher number of cases with shallow z i (<200 m) in winter (67.3%) than in summer (33.9%) and spring (54.5%). Thus, this pilot study helps delineate the impact of z i on C Rn at the site mainly for different regimes of ABL, in particular, during the times when the z i is above the measurement height. It is suggested that when the z i is well below the inlet height, measurements are most possibly indicative of the residual layer 222 Rn, an important issue that should be considered in the mass budget approach.

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Evaluation of Mixing-Height Retrievals from Automatic Profiling Lidars and Ceilometers in View of Future Integrated Networks in Europe

Cited by 247 publications

References 34 publications

Lidar-based remote sensing of atmospheric boundary layer height over land and ocean

Lidar-based remote sensing of atmospheric boundary layer height over land and ocean

Improved mixing height monitoring through a combination of lidar and radon measurements

Investigation of the atmospheric boundary layer depth variability and its impact on the ²²²Rn concentration at a rural site in France

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Evaluation of Mixing-Height Retrievals from Automatic Profiling Lidars and Ceilometers in View of Future Integrated Networks in Europe

Cited by 247 publications

References 34 publications

Lidar-based remote sensing of atmospheric boundary layer height over land and ocean

Lidar-based remote sensing of atmospheric boundary layer height over land and ocean

Improved mixing height monitoring through a combination of lidar and radon measurements

Investigation of the atmospheric boundary layer depth variability and its impact on the 222Rn concentration at a rural site in France

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Investigation of the atmospheric boundary layer depth variability and its impact on the ²²²Rn concentration at a rural site in France