Turbulent structure and scaling of the inertial subrange in a stratocumulus-topped boundary layer observed by a Doppler lidar

Tonttila, Juha; O’Connor, Ewan; Hellsten, Antti; Hirsikko, Anne; O’Dowd, Colin; Järvinen, Heikki; Räisänen, Petri

doi:10.5194/acp-15-5873-2015

Cited by 19 publications

(20 citation statements)

References 33 publications

(44 reference statements)

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“…We use µ = 1.5, which provides a good match with our experimental spectra, as also found in previous studies (Lothon et al, 2009;Tonttila et al, 2015). The parameter a can be expressed as a function of µ as…”

Section: Determination Of the Optimal Timescales To Retrieve From Lidmentioning

confidence: 67%

“…Following the approach in Tonttila et al (2015), we estimate the timescale corresponding to this transition wavelength by To compare the results from this approach with what we obtain from the comparison with dissipation rates from the sonic anemometer data, we apply this technique to the data from the Halo Stream Line for the whole period of XPIA and calculate the average timescales for different stability conditions at 100 m a.g.l. We obtain an average timescale of 32 s in stable conditions and 73 s in unstable conditions.…”

Section: Determination Of the Optimal Timescales To Retrieve From Lidmentioning

confidence: 99%

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Estimation of turbulence dissipation rate and its variability from sonic anemometer and wind Doppler lidar during the XPIA field campaign

2018

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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 ( ). 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 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 . We refine and extend an existing method to accommodate different atmospheric stability conditions. To validate our approach, we estimate 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 . Our analysis of this extensive dataset provides understanding of the climatology of turbulence dissipation over the course of the campaign. Further, the variability in with atmospheric stability, height, and wind speed is also assessed. Finally, we present how increases as nocturnal turbulence is generated during low-level jet events.

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Section: Determination Of the Optimal Timescales To Retrieve From Lidmentioning

confidence: 67%

Section: Determination Of the Optimal Timescales To Retrieve From Lidmentioning

confidence: 99%

Estimation of turbulence dissipation rate and its variability from sonic anemometer and wind Doppler lidar during the XPIA field campaign

2018

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“…This approach derives by integrating the turbulence spec- trum within the inertial subrange. To do so, the maximum length scale (and thus the sample size) to include in the calculation must be accurately chosen (Tonttila et al, 2015;Bodini et al, 2018). Here we use a local regression of the spectrum of the line-of-sight velocity to estimate the extension of the inertial subrange, as described and tested in Bodini et al (2019).…”

Section: Turbulence Dissipation Rate From Profiling Lidarsmentioning

confidence: 99%

Offshore Wind Turbines Will Encounter Very Low Atmospheric Turbulence

Bodini¹,

Lundquist²,

Kirincich³

2020

J. Phys.: Conf. Ser.

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Key Points:• strength and persistence of wind plant wakes depends on turbulence dissipation rate • turbulence dissipation rate offshore is small with a weak diurnal cycle • dissipation rate is larger when flow is from the land, which tends to be in wintertime at this site AbstractThe rapid growth of offshore wind energy requires accurate modeling of the wind resource, which can be depleted by wind farm wakes. Turbulence dissipation rate ( ) governs the accuracy of model predictions of hub-height wind speed and the development and erosion of wakes. Here we assess the variability of turbulence kinetic energy and using 13 months of observations from a profiling lidar deployed on a platform off the Massachusetts coast. Offshore, is 2 orders of magnitude smaller than onshore, with a subtle diurnal cycle. Wind direction largely influences the annual cycle of turbulence, with larger values in winter when the wind flows from the land, and smaller values in summer, when the wind is mainly from open ocean. Because of the weak turbulence, wind plant wakes will be stronger and persist farther downwind in summer.

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“…where k is the wave number, σ z is the standard deviation of the vertical component of the wind speed used to compute the spectrum, l z is the integral scale of the vertical velocity along the horizontal flow trajectory, and the parameter µ controls the curvature of the spectrum. We use µ = 1.5, which provides a good match with our experimental spectra, as also found in previous studies (Lothon et al, 2009;Tonttila et al, 2015). The parameter a can be expressed as a function of µ as a(µ) = π µ 5 6µ 1 2µ 1 3µ…”

Section: Determination Of the Optimal Timescales To Retrieve From Lidmentioning

confidence: 67%

“…Following the approach in Tonttila et al (2015), we estimate the timescale corresponding to this transition wavelength by Figure 10. Time series from 6 April 00:00 UTC to 10 April 2015 00:00 UTC comparing from sonic anemometers and the Halo Stream Line lidars at 100 m a.g.l., where the timescales for the lidars have been determined with both the proposed approaches (comparison with from sonic anemometers and fit with spectral models).…”

Section: Determination Of the Optimal Timescales To Retrieve From Lidmentioning

confidence: 99%

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Bodini¹

2018

Preprint

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Turbulent structure and scaling of the inertial subrange in a stratocumulus-topped boundary layer observed by a Doppler lidar

Cited by 19 publications

References 33 publications

Estimation of turbulence dissipation rate and its variability from sonic anemometer and wind Doppler lidar during the XPIA field campaign

Estimation of turbulence dissipation rate and its variability from sonic anemometer and wind Doppler lidar during the XPIA field campaign

Offshore Wind Turbines Will Encounter Very Low Atmospheric Turbulence

Response to Anonymous Referee #1

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