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Martin Flügges bilde

Martin Flügge

Ph.d.-kandidat
  • E-postmartin.flugge@uib.no
  • Besøksadresse
    Allégaten 41
    Realfagbygget
    5007 Bergen
    Rom 
    205
  • Postadresse
    Postboks 7803
    5020 Bergen

I obtained a bachelor’s degree in meteorology and oceanography in 2007 and a master’s degree in geophysics – climate in 2009. Currently, I am taking my PhD at the University of Bergen and work in the research field of boundary layer meteorology. I was also affiliated to the Norwegian Research School in Climate Dynamics (ResClim) and the Norwegian Centre for Offshore Wind Energy (NORCOWE).

Teaching assistant

  • GEOF310, Boundary layer turbulence in the atmospheric and ocean
  • GEOF301, Introduction to Master studies
Vitenskapelig artikkel
  • Vis forfatter(e) (2021). The COTUR project: Remote sensing of offshore turbulence for wind energy application. Atmospheric Measurement Techniques. 6137-6157.
  • Vis forfatter(e) (2021). Predictive Capability of WRF Cycling 3DVAR: LiDAR Assimilation at FINO1. Journal of Physics: Conference Series (JPCS). 17 sider.
  • Vis forfatter(e) (2019). Wind Stress in the Coastal Zone: Observations from a Buoy in Southwestern Norway . Atmosphere. 1-32.
  • Vis forfatter(e) (2017). 2D VAR single Doppler LIDAR vector retrieval and its application in offshore wind energy. Energy Procedia. 497-504.
  • Vis forfatter(e) (2016). Comparison of direct covariance flux measurements from an offshore tower and a buoy. Journal of Atmospheric and Oceanic Technology. 873-890.
  • Vis forfatter(e) (2016). Automated Measurements of Whitecaps on the Ocean Surface from a Buoy-Mounted Camera. Methods in oceanography. 14-31.
  • Vis forfatter(e) (2014). Characterization of the SUMO Turbulence Measurement System for Wind Turbine Wake Assessment. Energy Procedia. 173-183.
  • Vis forfatter(e) (2013). Wave-induced characteristics of atmospheric turbulence flux measurements. Energy Procedia. 102-112.
  • Vis forfatter(e) (2013). Preliminary results of the NORCOWE Direct Covariance Flux System for Ship based measurements. Energy Procedia. 128-136.
  • Vis forfatter(e) (2013). Atmospheric winter response to a projected future Antarctic sea-ice reduction: a dynamical analysis. Climate Dynamics. 2707-2718.
  • Vis forfatter(e) (2012). Sensor movement correction for direct turbulence measurements in the marine atmospheric boundary layer. Energy Procedia. 159-165.
Faglig foredrag
  • Vis forfatter(e) (2019). The COTUR campaign - measuring offshore turbulence and coherence with lidars.
  • Vis forfatter(e) (2019). The COTUR campaign - measuring offshore turbulence and coherence With lidars.
  • Vis forfatter(e) (2019). COTUR - Estimating coherence and turbulence with LIDARs.
  • Vis forfatter(e) (2018). NORCOWE Measurement campaigns.
  • Vis forfatter(e) (2018). COTUR Measuring coherence and turbulence with lidars.
  • Vis forfatter(e) (2017). The NORCOWE legacy - Data and Instrumentation.
  • Vis forfatter(e) (2017). Meteorological measurements during OBLEX-F1.
  • Vis forfatter(e) (2017). Air-Sea Interacton at Wind Energy Site in FINO1 Using DCF (Lidar) Measurements from OBLEX-F1 campaign.
  • Vis forfatter(e) (2016). NORCOWE contributions to improvements in measurement methods and measurement technique.
Populærvitenskapelig foredrag
  • Vis forfatter(e) (2021). A Mesoscale Model Sensitivity over the Southern North Sea: Comparison with Measurements and Impacts of Data Assimilation.
Vitenskapelig foredrag
  • Vis forfatter(e) (2021). Preliminary results of the COTUR project.
  • Vis forfatter(e) (2020). Preliminary results of the COTUR project.
  • Vis forfatter(e) (2016). Boundary-Layer Study at FINO1.
  • Vis forfatter(e) (2016). Boundary-Layer Study at FINO1.
  • Vis forfatter(e) (2015). Floating Platform Motion Correction Using Video Camera Images.
  • Vis forfatter(e) (2014). Characterization of the SUMO turbulence measurement system for wind turbine wake assessment.
  • Vis forfatter(e) (2013). Wave–induced characteristics of atmospheric turbulence flux measurements.
  • Vis forfatter(e) (2013). Application of the NORCOWE DCF System for Ship based measurements.
  • Vis forfatter(e) (2012). Sensor movement correction for direct turbulence measurements in the marine atmospheric boundary layer.
Intervju
  • Vis forfatter(e) (2019). Vindmøller til havs.
  • Vis forfatter(e) (2019). Vind viser vei.
  • Vis forfatter(e) (2019). Distriktsnyheter Rogaland.
Poster
  • Vis forfatter(e) (2020). The COTUR project: Remote sensing of offshore turbulence for wind energy application.
  • Vis forfatter(e) (2020). Study of Wind-Wave Interac2ons Based on a Wave-Modified Two Equa2on Model and Measurements at FINO1.
  • Vis forfatter(e) (2019). The OBLO infrastructure project - Measurement capabilities for offshore wind energy research in Norway.
  • Vis forfatter(e) (2019). Offshore wind activities within NORCE.
  • Vis forfatter(e) (2018). Wind Lidar measurement activities within NORCOWE.
  • Vis forfatter(e) (2017). Availability of the OBLO infrastructure for wind energy research in Norway.
  • Vis forfatter(e) (2016). OBLO instrumentation at FINO1.
  • Vis forfatter(e) (2015). The Offshore Boundary Layer Observatory (OBLO).
  • Vis forfatter(e) (2014). Field Measurements of Wave Breaking Statistics Using Video Camera for Offshore Wind Application.
  • Vis forfatter(e) (2014). Characterization of the SUMO turbulence measurement system for wind turbine wake assessment.
Brosjyre
  • Vis forfatter(e) (2019). Vindmåling på Obreatad Fyr.

Se fullstendig oversikt over publikasjoner i CRIStin.

Peer-review publications:

Cheynet, E., Flügge, M., Reuder, J., Jakobsen, J. B., Heggelund, Y., Svardal, B., Saavedra Garfias, P., Obhrai, C., Daniotti, N., Berge, J., Duscha, C., Wildmann, N., Husøy Onarheim, I., and Godvik, M., 2021: The COTUR project: Remote sensing of offshore turbulence for wind energy application, Atmos. Meas. Tech., 44(9),6137-6157. Online at: https://amt.copernicus.org/articles/14/6137/2021/

Flügge, M., M. Bakhoday-Paskyabi, J. Reuder and O. El Guernaoui, 2019: Wind stress in the coastal zone: Observations from a buoy in south-western Norway. Atmosphere, 2019, 10(9), 491. Online at https://doi.org/10.3390/atmos10090491

Cherakuru, N. W., R. Calhun, R. Krishnamurty, B. Svardal, J. Reuder and M. Flügge, 2017: 2D VAR single Doppler LIDAR vector retrieval and its application in offshore wind energy. Energy Procedia 2017 ;Volum 137, p. 497-504. Online at https://www.sciencedirect.com/science/article/pii/S1876610217353614

Bakhoday-Paskyabi, M., J. Reuder and M. Flügge, 2016: Automated Measurements of Whitecaps on the Ocean Surface from a Buoy-Mounted Camera. Methods in Oceanography, 17, 14-31. Online at http://www.sciencedirect.com/science/article/pii/S2211122015300281

Flügge, M., M. Bakhoday-Paskyabi, J. Reuder, J. B. Edson, and A. J. Plueddemann, 2016: Comparison of direct covariance flux measurements from an offshore tower and a buoy. Journal of Atmospheric and Oceanic Technology, 33(5), 873-890. Online at http://journals.ametsoc.org/doi/pdf/10.1175/JTECH-D-15-0109.1 

Båserud, L., M. Flügge, A. Bhandari and J. Reuder: Characterization of the SUMO turbulence measurement system for wind turbine wake assessment. Energy Procedia, 53, 173-183. http://www.sciencedirect.com/science/article/pii/S1876610214011035

Flügge, M., and J. Reuder, 2013 : Preliminary results of the NORCOWE direct covariance flux system for Ship based measurements. Energy Procedia, 35, 128-136. http://www.sciencedirect.com/science/article/pii/S1876610213012526#

Bakhoday-Paskyabi, M., M. Flügge, J. B. Edson, and J. Reuder, 2013: Wave–induced characteristics of atmospheric turbulence flux measurements. Energy Procedia, 35, 102-112. http://www.sciencedirect.com/science/article/pii/S1876610213012496#

Flügge, M., J. B. Edson, and J. Reuder, 2012: Sensor movement correction for direct turbulence measurements in the marine atmospheric boundary layer. Energy Procedia, 24, 159-165. http://www.sciencedirect.com/science/article/pii/S187661021201137X

Bader J., M. Flügge, N.G. Kvamstø, M.D.S. Mesquita, and A. Voigt, 2013: Atmospheric winter response to a projected further Antarctic sea-ice reduction: a dynamical analysis, Climate Dynamics 40 (11-12), 2707-2718, online at https://link.springer.com/article/10.1007/s00382-012-1507-9

 

Education

2010-present: PhD in Boundary-Layer Meteorology at UiB

2007-2009: Master in Geophysics – Climate at UiB

2004-2007: Bachelor in meteorology and oceanography at UiB

Forskergrupper