Asymmetric behaviour of turbulence in the wake of wind farms caused by the Coriolis force

TL;DR

This study investigates how the Coriolis force causes asymmetric turbulence in offshore wind farm wakes, revealing that veer effects lead to TKE streaks on opposite sides in northern and southern hemispheres, with implications for wake recovery.

Contribution

The paper demonstrates that the Coriolis force induces asymmetric turbulence in wind farm wakes through veer effects, supported by LES simulations and field data comparisons.

Findings

TKE streaks appear on opposite sides in northern and southern hemispheres.

Coriolis-induced veer causes increased TKE production at the top of the ABL.

TKE streaks modestly enhance wake recovery.

Abstract

Large offshore wind farm wakes in shallow atmospheric boundary layers (ABL) exhibit often an asymmetric behaviour when observed through Synthetic-Aperture-Radar or simulated through Large-Eddy Simulations (LES). In previous LES of wind farms in the northern hemisphere, the asymmetry manifests as a streak at the left side of the wake, looking downstream, where the turbulence kinetic energy (TKE) is greater than the surrounding flow. This work aims at clarifying the physical mechanism that leads to the formation of such a phenomenon. Identifying the Coriolis force as one possible source of asymmetry in the resolved physics, we simulate a real wind farm located in the German Bight operating under different ABLs: one representative of the northern hemisphere; one of the southern hemisphere; and three fictitious ABLs where the Coriolis effects on the inflow and wake, i.e. veer and the wake deflecting force, are removed individually or altogether. Our results show that the TKE streak appears on the opposite side of the wake, i.e. the right one, in the southern hemisphere, and it is primarily caused by veer in the incoming flow, a result of the Coriolis force in a marine ABL. The process involves a larger TKE production which originates from a larger vertical shear promoted where the undisturbed veer profile converges towards the wake in the top part of the ABL. We find that the TKE streak improves the farm wake recovery modestly. Finally, we compare the asymmetry modelled by LES with those observed in several on-field measurements, finding striking similarities.