Rudolf Hankers scite author profile

More than 12 GW of offshore wind turbines are currently in operation in European waters. To optimise the use of the marine areas, wind farms are typically clustered in units of several hundred turbines. Understanding wakes of wind farms, which is the region of momentum and energy deficit downwind, is important for optimising the wind farm layouts and operation to minimize costs. While in most weather situations (unstable atmospheric stratification), the wakes of wind turbines are only a local effect within the wind farm, satellite imagery reveals wind-farm wakes to be several tens of kilometres in length under certain conditions (stable atmospheric stratification), which is also predicted by numerical models. The first direct in situ measurements of the existence and shape of large wind farm wakes by a specially equipped research aircraft in 2016 and 2017 confirm wake lengths of more than tens of kilometres under stable atmospheric conditions, with maximum wind speed deficits of 40%, and enhanced turbulence. These measurements were the first step in a large research project to describe and understand the physics of large offshore wakes using direct measurements, together with the assessment of satellite imagery and models.

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Airborne turbulence measurements in the lower troposphere onboard the research aircraft Dornier 128-6, D-IBUF

Corsmeier¹,

Hankers²,

Wieser³

2001

metz

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In situ airborne measurements of atmospheric and sea surface parameters related to offshore wind parks in the German Bight

Lampert

Bärfuss

Platis

et al. 2020

Earth Syst. Sci. Data

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Abstract. Between 6 September 2016 and 15 October 2017, meteorological measurement flights were conducted above the German Bight in the framework of the project WIPAFF (Wind Park Far Field). The scope of the measurements was to study long-range wakes with an extent larger than 10 km behind entire wind parks, and to investigate the interaction of wind parks and the marine atmospheric boundary layer. The research aircraft Dornier 128 of the Technische Universität (TU) Braunschweig performed in total 41 measurement flights during different seasons and different stability conditions. The instrumentation consisted of a nose boom with sensors for measuring the wind vector, temperature and humidity, and additionally sensors for characterizing the water surface, a surface temperature sensor, a laser scanner and two cameras in the visible and infrared wavelength range. A detailed overview of the aircraft, sensors, data post-processing and flight patterns is provided here. Further, averaged profiles of atmospheric parameters illustrate the range of conditions. The potential use of the data set has been shown already by first publications. The data are publicly available in the world data centre PANGAEA (https://doi.org/10.1594/PANGAEA.902845; Bärfuss et al., 2019a).

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Vertical stratification of the air microbiome in the lower troposphere

Drautz–Moses

Luhung

Gusareva

et al. 2022

Proc. Natl. Acad. Sci. U.S.A.

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The troposphere constitutes the final frontier of global ecosystem research due to technical challenges arising from its size, low biomass, and gaseous state. Using a vertical testing array comprising a meteorological tower and a research aircraft, we conducted synchronized measurements of meteorological parameters and airborne biomass (n = 480) in the vertical air column up to 3,500 m. The taxonomic analysis of metagenomic data revealed differing patterns of airborne microbial community composition with respect to time of day and height above ground. The temporal and spatial resolution of our study demonstrated that the diel cycle of airborne microorganisms is a ground-based phenomenon that is entirely absent at heights >1,000 m. In an integrated analysis combining meteorological and biological data, we demonstrate that atmospheric turbulence, identified by potential temperature and high-frequency three-component wind measurements, is the key driver of bioaerosol dynamics in the lower troposphere. Multivariate regression analysis shows that at least 50% of identified airborne microbial taxa (n = ∼10,000) are associated with either ground or height, allowing for an understanding of dispersal patterns of microbial taxa in the vertical air column. Due to the interconnectedness of atmospheric turbulence and temperature, the dynamics of microbial dispersal are likely to be impacted by rising global temperatures, thereby also affecting ecosystems on the planetary surface.

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In-situ airborne measurements of atmospheric and sea surface parameters related to offshore wind parks in the German Bight

Lampert¹,

Bärfuss²,

Platis³

et al. 2019

Preprint

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Abstract. Between 6 September 2016 and 15 October 2017, meteorological measurement ﬂights were conducted above the German Bight in the framework of the project WIPAFF (Wind Park Far Field). The scope of the measurements was to investigate long-range wakes with extent larger than 10 km behind entire wind parks, and to investigate the interaction of wind parks and the marine atmospheric boundary layer. The research aircraft Dornier 128 of TU Braunschweig performed in total 41 measurement ﬂights during different seasons and different stability conditions. The instrumentation consisted of a nose boom with sensors for measuring the wind vector, temperature and humidity, and additionally sensors for characterizing the water surface, a surface temperature sensor, a laser scanner, and two cameras in the visible and infrared wavelength range. A detailed overview of the aircraft, sensors, data post processing and ﬂight patterns is provided here. Further, averaged proﬁles of atmospheric parameters illustrate the range of conditions. The potential use of the data set is shown by ﬁrst publications. The data are publicly available in the world data center PANGAEA (https://doi.org/10.1594/PANGAEA.902845, Bärfuss et al., 2019).

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Rudolf Hankers

First in situ evidence of wakes in the far field behind offshore wind farms

Airborne turbulence measurements in the lower troposphere onboard the research aircraft Dornier 128-6, D-IBUF

In situ airborne measurements of atmospheric and sea surface parameters related to offshore wind parks in the German Bight

Vertical stratification of the air microbiome in the lower troposphere

In-situ airborne measurements of atmospheric and sea surface parameters related to offshore wind parks in the German Bight

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