Scientific challenges to characterizing the wind resource in the marine atmospheric boundary layer

Shaw, W. J.; Berg, Larry K.; Debnath, Mithu; Deskos, Georgios; Draxl, Caroline; Ghate, Virendra P.; Hasager, Charlotte Bay; Kotamarthi, V. R.; Mirocha, Jeffrey D.; Muradyan, Paytsar; Pringle, William; Turner, David D.; Wilczak, James M.

doi:10.5194/wes-7-2307-2022

Cited by 16 publications

(7 citation statements)

References 234 publications

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“…➢ Continuing working towards unifying oceanographic and ABL meteorology frameworks, from a wind energy perspective as discussed in (Shaw et al 2022).…”

Section: Conclusion and Suggestions For Future Workmentioning

confidence: 99%

Underestimation of strong wind speeds offshore in ERA5: evidence, discussion, and correction

Gandoin,

Garza

2024

Preprint

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Abstract. Offshore Wind power plants have become an important element of the European electrical grid. Studies of metocean site conditions (wind, sea state, currents, water levels) form a key input to the design of these large infrastructure projects. Such studies heavily rely on reanalysis datasets which provide decades-long model time series over large areas. In this article, we address a known deficiency of one these reanalysis datasets, ERA5, namely that it underestimates strong wind speeds offshore. For doing so, comparisons are made against CFSR/CFSv2 reanalyses as well as high quality wind energy specific in-situ measurements from floating LiDAR systems. The ERA5 surface drag formulation and its sea state dependency are analysed in detail, the conditions of the bias identified, and a correction method is suggested. The article concludes with proposing practical and simple ways to incorporate publicly available, high-quality wind energy measurement datasets in air-sea interaction studies alongside legacy measurements such as met buoys.

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“…➢ Continuing working towards unifying oceanographic and ABL meteorology frameworks, from a wind energy perspective as discussed in (Shaw et al 2022).…”

Section: Conclusion and Suggestions For Future Workmentioning

confidence: 99%

Underestimation of strong wind speeds offshore in ERA5: evidence, discussion, and correction

Gandoin,

Garza

2024

Preprint

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“…Wind energy is expected to have a key share in the new generation mix, and by necessity much of this contribution will come from offshore wind turbines. However, there remain some challenges in fully characterizing the performance and dynamics of offshore wind turbines within the marine atmospheric boundary layer [1]. Further research is needed to mitigate challenges and uncertainties to advance the growth of offshore wind energy.…”

Section: Introductionmentioning

confidence: 99%

Large-eddy simulation study on wave-wake interactions past an offshore wind turbine

Ciri

2024

J. Phys.: Conf. Ser.

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Large-eddy simulations (LES) of the flow past an offshore wind turbine under different underlying wave fields have been performed. A one-way coupling between the air and water flows has been realized through a hybrid immersed-boundary/level-set method. The velocity in the water domain is forced with the potential flow solution, while the response of the atmospheric boundary layer to the changes in the sea-surface height (tracked by the level-set equation) is simulated with a LES approach coupled to a rotating actuator disk model to mimic the effect of the wind turbine. A parametric study has been performed varying the wave period and wavelength while keeping the amplitude constant, resulting in different wave age parameters ranging from young developing waves to old swell waves. The wave field has a significant effect on the lower region of the atmospheric boundary layer, slowing down the wind field in proximity of the air-water interface and considerably increasing the local turbulence kinetic energy (TKE). The interaction between the wave evolution and the TKE results in a non-monotonic trend of the wake recovery rate with the wave age, when compared to the baseline value in the wake of a turbine over a flat wall. Both developed waves results in a lower recovery rate, whereas intermediate-age waves present a larger value than the baseline. The increased TKE in the lower layers of the rotor revolution induces an increased fluctuating component in the power production and blade loads. Nevertheless, for the parameters considered in this study, the spectra of the blade loads do not show a clear signature at the wave frequency, but the increased fluctuating component occurs over a broad range of frequencies.

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“…However, SAR-derived wind fields are surface wind fields, it is thus necessary to proceed to a vertical extrapolation within the marine atmospheric boundary layer (ABL). The understanding of the geophysical processes in the marine ABL remains quite incomplete, especially the air-sea interactions governing the dynamics and thermodynamics of the surface layer [13]. The use of power law or logarithmic law that is derived from land-based observations can be questionable offshore and associated errors for vertical extrapolations will increase with vertical distance (even with tunable coefficients).…”

Section: Introductionmentioning

confidence: 99%

High-resolution satellite observations to account for coastal gradient in wind resource assessment: application to French coastal areas

Cathelain

Husson

Berger

et al. 2023

J. Phys.: Conf. Ser.

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The 18-year database of European Synthetic Aperture Radars (SAR) provides worldwide surface wind measurements at one-kilometre resolution. Through an innovative vertical extrapolation methodology published in 2022, these long-term, wide, and high-resolution observations can complement in-situ observations and mesoscale modelling for offshore wind resource assessment. The methodology is based on four steps: (i) derivation of the 10-min SAR surface winds from SAR sea surface roughness, (ii) a site- and time-independent machine learning algorithm based on a large buoy network to correct SAR winds due to biases inherent to the characteristics of the satellite sensors and wind retrieval methodology, (iii) extrapolation up to a few hundred meters based on a second machine learning algorithm trained with in-situ observations and physical parameters from a high-resolution mesoscale model related to e.g. atmospheric stability, and (iv) a final post-processing step to correct for low temporal sampling of the SAR database (a couple of days in Europe for one satellite) and retrieve wind statistics. The resulting output is a 1-km resolution wind atlas in a large (> 3000 km2) offshore and/or coastal area where strong coastal gradients will be accounted for. It can also integrate directly the estimation of the extractible wind power. Here, an improvement of the extrapolation method is presented and applied to a French offshore area in South Brittany. The wind atlas obtained with SAR is found to display a much finer level of details and estimate more precisely the coastal gradient.

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Scientific challenges to characterizing the wind resource in the marine atmospheric boundary layer

Cited by 16 publications

References 234 publications

Underestimation of strong wind speeds offshore in ERA5: evidence, discussion, and correction

Underestimation of strong wind speeds offshore in ERA5: evidence, discussion, and correction

Large-eddy simulation study on wave-wake interactions past an offshore wind turbine

High-resolution satellite observations to account for coastal gradient in wind resource assessment: application to French coastal areas

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