Richard Davy

Job Position: 
Senior Researcher
Research Group: 
E-mail: 
Phone: 
+47 406 43 028

Academic Degree:

Doctor in Physics and Astronomy, York University, Toronto, Ontario, Canada, 2009
Richard Davy Portrait

Peer Review Publications and Books

32 total publications.

2020

  1. Gnatiuk N, Radchenko I, Davy R, Morozov E, Bobylev L. Simulation of factors affecting Emiliania huxleyi blooms in Arctic and sub-Arctic seas by CMIP5 climate models: model validation and selection. Biogeosciences. 2020;17(4).
  2. Davy R, Outten S. The Arctic Surface Climate in CMIP6: Status and Developments since CMIP5. Journal of Climate. 2020;33(18).
  3. Johannessen OM, Sandven S, Davy R, Olason E. Marginal Ice Zone and Ice-Air-Ocean Interactions. 2020.

2019

  1. Outten S, Davy R, Chen L. Eurasian Cooling Patterns in the CMIP5 Climate Models. Izvestiya, Atmospheric and Oceanic Physics. 2019;

2018

  1. Yano J-I, Ziemianski M, Cullen M, Termonia P, Onvlee J, Bengtsson L, et al. Scientific challenges of convective-scale numerical weather prediction. Bulletin of The American Meteorological Society - (BAMS). 2018;
  2. Davy R, Chen L, Hanna E. Arctic amplification metrics. International Journal of Climatology. 2018;38(12).
  3. Varentsov M, Konstantinov P, Baklanov A, Esau I, Miles V, Davy R. Anthropogenic heating strongly amplifies the urban heat island in Arctic cities. Atmospheric Chemistry and Physics. 2018;18.
  4. Davy R. The Climatology of the Atmospheric Boundary Layer in Contemporary Global Climate Models. Journal of Climate. 2018;31(22).
  5. Yurova AY, Bobylev L, Zhu Y, Davy R, Korzhikov AY. Atmospheric heat advection in the Kara Sea region under main synoptic processes. International Journal of Climatology. 2018;39(1).
  6. Varentsov M, Konstantinov P, Baklanov A, Esau I, Miles V, Davy R. Anthropogenic and natural drivers of a strong winter urban heat island in a typical Arctic city. Atmospheric Chemistry and Physics. 2018;18(23).

2017

  1. Chernokulsky A, Esau I, Bulygina ON, Davy R, Mokhov II, Outten S, et al. Climatology and interannual variability of cloudiness in the Atlantic Arctic from surface observations since the late nineteenth century. Journal of Climate. 2017;30(6).
  2. Davy R, Gnatiuk N, Pettersson LH, Bobylev L. Climate change impacts on wind energy potential in the European domain with a focus on the Black Sea. Renewable & Sustainable Energy Reviews. 2017;81(2).
  3. Thorne P, Madonna F, Schulz JB, Oakley T, Ingleby B, Rosoldi M, et al. Making better sense of the mosaic of environmental measurement networks: a system-of-systems approach and quantitative assessment. Geoscientific Instrumentation, Methods and Data Systems. 2017;6(2).
  4. Boero F, Foglini S, Frachetti P, Goriup E, Macpherson S, Planes T, et al. CoCoNet: Towards Coast to Coast Networks of Marine Protected Areas (from the shore to the high and deep sea), coupled with Sea-Based Wind Energy Potential. SCIRES-IT SCIentific RESearch and Information Technology. 2017;6.

2016

  1. Esau I, Miles V, Davy R, Miles MW, Kurchatova A. Trends in the normalized difference vegetation index (NDVI) associated with urban development of Northern West Siberia. Atmospheric Chemistry and Physics. 2016;16(15).
  2. Davy R, Esau I. Surface air temperature changes in the high-latitude boundary layer. Report Series in Aerosol Science. 2016;180.
  3. Esau I, Davy R. Stably stratified planetary boundary layer effects in northern hemisphere climate. Fundamentalnaya i prikladnaya gidrofizika. 2016;9(3).
  4. Boero F, Foglini S, Frachetti P, Goriup E, Macpherson S, Planes T, et al. CoCoNet: Towards Coast to Coast Networks of Marine Protected Areas (from the shore to the high and deep sea), coupled with Sea-Based Wind Energy Potential. SCIRES-IT : SCIentific RESearch and Information Technology. 2016;6.
  5. Thorne P, Menne MJ, Williams CN, Rennie JJ, Lawrimore JH, Vose RS, et al. Reassessing changes in diurnal temperature range: A new data set and characterization of data biases. Journal of Geophysical Research (JGR): Atmospheres. 2016;121(10).
  6. Davy R, Esau I. Differences in the efficacy of climate forcings explained by variations in atmospheric boundary layer depth. Nature Communications. 2016;7.
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