Can Water Vapour Raman Lidar Resolve Profiles of Turbulent Variables in the Convective Boundary Layer?

Wulfmeyer, Volker; Pal, Sandip; Turner, David D.; Wagner, E

doi:10.1007/s10546-010-9494-z

Cited by 86 publications

(122 citation statements)

References 66 publications

Supporting

Mentioning

113

Contrasting

Order By: Relevance

“…Increasing water vapour variance upwards in this layer produces the observed patterns of refractive change during the day. Observations (Wulfmeyer et al 2010) and modelling (Stull 1988) elsewhere indicate that upward-increasing variance of specific vapour humidity in the mixed layer is to be expected, which is consistent with our observations. Paths to the ground surface above 800 m a.s.l.…”

Section: Summary and Fit To The Ablsupporting

confidence: 92%

“…To the upper right is a profile of the specific humidity through the daytime ABL based on the BOMEX results (Siebesma et al 2003), which can be regarded as the baseline ocean ABL state for the atmosphere around Montserrat. The variance of the specific humidity is shown schematically (no units) based on observations and modelling (Stull 1988;Wulfmeyer et al 2010). This shows very high levels of specific humidity variance around the entrainment layer falling to much lower levels at the base of the mixed layer lines of evidence to properly parameterise the degree of turbulence of the ABL layers.…”

Section: Summary and Fit To The Ablmentioning

confidence: 99%

See 1 more Smart Citation

The Variability of Refractivity in the Atmospheric Boundary Layer of a Tropical Island Volcano Measured by Ground-Based Interferometric Radar

Wadge

Costa

Pascal

et al. 2016

Boundary-Layer Meteorol

View full text Add to dashboard Cite

For 24 h we measured continuously the variability of atmospheric refractivity over a volcano on the tropical island of Montserrat using a ground-based radar interferometer. We observed variations in phase that we interpret as due to changing water vapour on the propagation path between the radar and the volcano and we present them here in the context of the behaviour of the atmospheric boundary layer over the island. The water vapour behaviour was forced by diurnal processes, the passage of a synoptic-scale system and the presence of a plume of volcanic gas. The interferometer collected images of amplitude and phase every minute. From pairs of phase images, interferograms were calculated and analyzed every minute and averaged hourly, together with contemporaneous measurements of zenith delays estimated from a network of 14 GPS receivers. The standard deviation of phase at two sites on the volcano surface spanned a range of about 1-5 radians, the lowest values occurring at night on the lower slopes and the highest values during the day on the upper slopes. This was also reflected in spatial patterns of variability. Two-dimensional profiles of radar-measured delays were modelled using an atmosphere with water vapour content decreasing upwards and water vapour variability increasing upwards. Estimates of the effect of changing water vapour flux from the volcanic plume indicate that it should contribute only a few percent to this atmospheric variability. A diurnal cycle within the lower boundary layer producing a turbulence-dominated mixed layer during the day and stable layers at night is consistent with the observed refractivity.

show abstract

Section: Summary and Fit To The Ablsupporting

confidence: 92%

Section: Summary and Fit To The Ablmentioning

confidence: 99%

The Variability of Refractivity in the Atmospheric Boundary Layer of a Tropical Island Volcano Measured by Ground-Based Interferometric Radar

Wadge

Costa

Pascal

et al. 2016

Boundary-Layer Meteorol

View full text Add to dashboard Cite

show abstract

“…The agreement between the airborne and ground lidar flux profiles is fairly good. A recent study with another ground-based water vapour Raman lidar corroborates our finding that profiles of turbulent variables in the CBL can in principal be obtained with such systems (Wulfmeyer et al, 2010).…”

Section: Fluxes Over the Rhine Valleysupporting

confidence: 87%

Latent heat flux measurements over complex terrain by airborne water vapour and wind lidars

Kiemle

Wirth

Fix

et al. 2011

Quart J Royal Meteoro Soc

View full text Add to dashboard Cite

“…Remote sensing techniques overcome these limitations and cover larger ranges simultaneously and continuously. Monitoring moisture fluctuations with high resolution for turbulence studies is a challenging task due to the noise limitation of these instruments; nevertheless, new techniques based on lidar are capable of providing data with sufficient precision and accuracy Wulfmeyer et al 2010Wulfmeyer et al , 2015. Couvreux et al (2005) compared the results of airborne water vapour DIAL measurements from the IHOP campaign with LES for a growing CBL.…”

Section: Introductionmentioning

confidence: 99%

“…Whereas it is also possible to derive higher-order moments with water vapour Raman lidar, Wulfmeyer et al (2010) and Turner et al (2014) demonstrated that the noise level in daytime turbulence profiles is much larger than for water vapour DIAL. Therefore, water vapour Raman lidar turbulence profiles are strongly limited to measurements of third-and fourth-order moments.…”

Section: Introductionmentioning

confidence: 99%

Turbulent Humidity Fluctuations in the Convective Boundary Layer: Case Studies Using Water Vapour Differential Absorption Lidar Measurements

Muppa

Behrendt

Späth

et al. 2015

Boundary-Layer Meteorol

Self Cite

View full text Add to dashboard Cite

Turbulent humidity fluctuations in the convective boundary layer (CBL) under clear-sky conditions were investigated by deriving moments up to fourth-order. Highresolution humidity measurements were collected with a water vapour differential absorption lidar system during the HD(CP) 2 Observational Prototype Experiment (HOPE). Two cases, both representing a well-developed CBL around local noon, are discussed. While the first case (from the intensive observation period (IOP) 5 on 20 April 2013) compares well with what is considered typical CBL behaviour, the second case (from IOP 6 on 24 April 2013) shows a number of non-typical characteristics. Both cases show similar capping inversions and wind shear across the CBL top. However, a major difference between both cases is the advection of a humid layer above the CBL top during IOP 6. While the variance profile of IOP 5 shows a maximum at the interfacial layer, two variance peaks are observed near the CBL top for IOP 6. A marked difference can also be seen in the third-order moment and skewness profiles: while both are negative (positive) below (above) the CBL top for IOP 5, the structure is more complex for IOP 6. Kurtosis is about three for IOP 5, whereas for IOP 6, the distribution is slightly platykurtic. We believe that the entrainment of an elevated moist layer into the CBL is responsible for the unusual findings for IOP 6, which suggests that it is important to consider the structure of residual humidity layers entrained into the CBL.

show abstract

Can Water Vapour Raman Lidar Resolve Profiles of Turbulent Variables in the Convective Boundary Layer?

Cited by 86 publications

References 66 publications

The Variability of Refractivity in the Atmospheric Boundary Layer of a Tropical Island Volcano Measured by Ground-Based Interferometric Radar

The Variability of Refractivity in the Atmospheric Boundary Layer of a Tropical Island Volcano Measured by Ground-Based Interferometric Radar

Latent heat flux measurements over complex terrain by airborne water vapour and wind lidars

Turbulent Humidity Fluctuations in the Convective Boundary Layer: Case Studies Using Water Vapour Differential Absorption Lidar Measurements

Contact Info

Product

Resources

About