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Stephanie Mayer

Guest Researcher
  • E-mailstephanie.mayer@uib.no
  • Visitor Address
    Allégaten 70
    5007 Bergen
  • Postal Address
    Postboks 7803
    5020 Bergen
Academic article
  • Show author(s) (2023). Warmer and wetter: Outlining climate services for snow-dependent tourism in Norway – The case of Lofoten. Climate Services. 11 pages.
  • Show author(s) (2022). The stable atmospheric boundary layer over snow-covered sea ice: Model evaluation with fine-scale ISOBAR18 observations. Quarterly Journal of the Royal Meteorological Society. 2031-2046.
  • Show author(s) (2022). "It´s in Our DNA": Climate Change and the Perceived Resilience and Adaptive Capacity in Nature-Based Tourism in Lofoten, Norway. Weather, Climate, and Society. 177-190.
  • Show author(s) (2021). The Innovative Strategies for Observations in the Arctic Atmospheric Boundary Layer Project (ISOBAR) — Unique fine-scale observations under stable and very stable conditions . Bulletin of The American Meteorological Society - (BAMS). 218-243.
  • Show author(s) (2020). How grid-spacing and convection representation affected the wind speed forecasts of four polar lows. Quarterly Journal of the Royal Meteorological Society.
  • Show author(s) (2018). Innovative strategies for observations in the Arctic atmospheric boundary layer (ISOBAR)—The Hailuoto 2017 Campaign. Atmosphere. 29 pages.
  • Show author(s) (2018). An Evolving Framework for Advancing Climate Services in Norway . EOS.
  • Show author(s) (2017). Land-atmosphere coupling in EURO-CORDEX evaluation experiments. Journal of Geophysical Research (JGR): Atmospheres. 79-103.
  • Show author(s) (2017). Downscaling an intense precipitation event in complex terrain: the importance of high grid resolution. Tellus A: Dynamic Meteorology and Oceanography. 1-15.
  • Show author(s) (2015). Regional climate hindcast simulations within EURO-CORDEX: Evaluation of a WRF multi-physics ensemble. Geoscientific Model Development. 603-618.
  • Show author(s) (2015). Identifying added value in high-resolution climate simulations over Scandinavia. Tellus A: Dynamic Meteorology and Oceanography. 1-18.
  • Show author(s) (2013). The simulation of European heat waves from an ensemble of regional climate models within the EURO-CORDEX project. Climate Dynamics. 2555-2575.
  • Show author(s) (2012). Profiling the arctic stable boundary layer in Advent Valley, Svalbard : measurements and simulations. Boundary-Layer Meteorology. 507-526.
  • Show author(s) (2012). FLOHOF 2007: an overview of the mesoscale meteorological field campaign at Hofsjokull, Central Iceland. Meteorology and atmospheric physics (Print). 1-13.
  • Show author(s) (2012). Atmospheric profiling with the UAS SUMO: A new perspective for the evaluation of fine-scale atmospheric models. Meteorology and atmospheric physics (Print). 15-26.
  • Show author(s) (2012). A ´no-flow-sensor` wind estimation algorithm for Unmanned Aerial Systems. International Journal of Micro Air Vehicles. 15-29.
  • Show author(s) (2009). The Small Unmanned Meteorological Observer SUMO: A new tool for atmospheric boundary layer research. Meteorologische Zeitschrift. 141-147.
  • Show author(s) (2008). SUMO: A Small Unmanned Meteorological Observer for atmospheric boundary layer research. IOP Conference Series: Earth and Environmental Science (EES). 10 pages.
Report
  • Show author(s) (2023). Helhetlig tiltaksplan og klimasårbarhetsanalyse for Sokndalsvassdraget. 486. 486. .
  • Show author(s) (2021). A short technical summary of the RCN-financed research projects Postclim and R3. .
  • Show author(s) (2020). MET Report: Verification metrics and diagnostics appropriate for the (maritime) Arctic. .
  • Show author(s) (2020). Analyse av klimautvikling i kyst- og innlandsregionen i Rogaland – temperatur, nedbør og vind. .
  • Show author(s) (2019). Climate in Svalbard 2100 . 1/2019. 1/2019. .
  • Show author(s) (2018). Climatic changes in short duration extreme precipitation and rapid onset flooding - implications for design values. .
  • Show author(s) (2017). Climate in Norway 2100 - a knowledge base for climate adaptation. .
  • Show author(s) (2015). Klima i Norge 2100 - Kunnskapsgrunnlag for klimatilpasning oppdatert 2015. .
Lecture
  • Show author(s) (2021). Applying the METRo model for road-condition  forecasting in Norway.
  • Show author(s) (2020). Klimautvikling i Norge, med fokus på Hordaland.
  • Show author(s) (2020). Klimautvikling i Norge.
  • Show author(s) (2020). Framtidens Norge.
  • Show author(s) (2019). National Climate Services in Norway.
  • Show author(s) (2017). The Isobar project - Observations on the stable polar Atmospheric Boundary Layer from Remotely Piloted Aircraft Systems.
  • Show author(s) (2016). The ISOBAR project (2016–2018) – Observations on the stable polar Atmospheric Boundary Layer from Remotely Piloted Aircraft Systems.
  • Show author(s) (2016). Climate in Norway 2100.
Academic lecture
  • Show author(s) (2023). Rain, sleet and snow under global warming at Norwegian tourist destinations.
  • Show author(s) (2021). “It’s in our DNA”: Climate change and perceived resilience and adaptive capacity in nature-based tourism in Lofoten, Norway.
  • Show author(s) (2021). Warmer and wetter: Local hydro-meteorological impacts of global climate change on nature-based tourism in Norway – destination Lofoten.
  • Show author(s) (2021). Hvordan kan klimaendringer påvirke stivandring?
  • Show author(s) (2021). Coping with darkening peaks.
  • Show author(s) (2019). Climate Change Impacts on Norwegian Nature based Tourism. The case of Tourism Transport Infrastructure.
  • Show author(s) (2018). The ISOBAR project on stable boundary layers – The two campaigns on Hailuoto 2017 and 2018.
  • Show author(s) (2016). The ISOBAR project (2016-2018) - Observations on the stable polar Atmospheric Boundary Layer from Remotely Piloted Aircraft Systems.
  • Show author(s) (2011). TheUAS SUMO: A successful story of an alternative tool foratmospheric boundary layer studies.
  • Show author(s) (2010). The UAS SUMO: A new tool for boundary layer research.
  • Show author(s) (2009). Simultaneous profiling of the Arctic Atmospheric Boundary Layer.
  • Show author(s) (2008). SUMO: A Small Unmanned Meteorological observer for atmospheric boundary layer research.
  • Show author(s) (2008). SUMO: A Small Unmanned Meteorological Observer for atmospheric boundary layer research.
  • Show author(s) (2008). SUMO: A Small Unmanned Meteorological Observer for atmospheric boundary layer research.
Popular scientific article
  • Show author(s) (2018). Ekstremnedbør i et klima i forandring. Naturen. 246-251.
  • Show author(s) (2016). Norges klimafremtid: Varmere og enda våtere. Naturen. 12-20.
Doctoral dissertation
  • Show author(s) (2011). Application and Improvement of the Unmanned Aerial System SUMO for atmospheric boundary layer studies.
Poster
  • Show author(s) (2021). How grid-spacing and convection representation affected the wind speed forecasts of four polar lows.
  • Show author(s) (2019). Using and developing climate indices for nature-based tourism in Norway .
  • Show author(s) (2017). Downscaling an intense precipitation event in complex terrain: The importance of high grid resolution.
  • Show author(s) (2017). Climate Services at the Bjerknes Centre.
  • Show author(s) (2016). The ISOBAR project (2016–2018) – Observations on the stable polar Atmospheric Boundary Layer from Remotely Piloted Aircraft Systems.
  • Show author(s) (2016). Non-­stationary extreme value analysis for precipitation over Norway.
  • Show author(s) (2014). Validation of two high-resolution climate simulations over Scandinavia.
  • Show author(s) (2014). Validation of soil moisture and surface fluxes in EURO-CORDEX simulations as part of land-atmosphere coupling analysis.
  • Show author(s) (2014). Identifying added value in two high-resolution climate simulations over Scandinavia.
  • Show author(s) (2014). Evaluation of a WRF-hindcast ensemble within EURO-CORDEX.
  • Show author(s) (2013). Identification of robust climate change patterns in Euro- CORDEX simulations for Europe at +2°C global warming.
  • Show author(s) (2013). Evaluation of regional climate impacts of the North Atlantic Oscillation in the Bjerknes Centre's CORDEX-Europe simulations.
  • Show author(s) (2013). Assessing projected changes in heat waves over Northern Europe using two regional climate models at 8-km resolution.
  • Show author(s) (2012). The Unmanned Aerial System SUMO: an alternative measurement tool for polar boundary layer studies.
  • Show author(s) (2012). Assessment of extreme precipitation over Northern Europe using WRF as a regional climate model within the RiskChange-project.
  • Show author(s) (2011). Risk-based design principles for energyinstallations due to climate change effects in the North Sea: Afirst validation of the ADAPT-Petromaks WRF climateruns.
  • Show author(s) (2010). Investigating the early springtime stable atmospheric boundary layer in Adventdalen (Spitsbergen).
  • Show author(s) (2009). The meteorological UAV SUMO: A new perspective for the evaluation of atmospheric boundary layer schemes in fine-scale atmospheric models.
Academic literature review
  • Show author(s) (2024). Revealing trends in extreme heatwave intensity: Applying the UNSEEN approach to Nordic countries. Environmental Research Letters. 1-10.

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