Biblio
Filtre: Forfatter er Davy, Richard [Slett Alle Filtre]
Arctic Sea-Level Change in Remote Sensing and New Generation Climate Models. Advances in Remote Sensing Technology and the Three Poles (2022).doi:10.1002/9781119787754
The climate role of shallow stably stratified atmospheric boundary layers. Proceedings of the 1st Pan-Eurasian Experiment (PEEX) Conference and the 5th PEEX Meeting. Report Series in Aerosol Science No. 163 (2015) (2015).
Marginal Ice Zone and Ice-Air-Ocean Interactions. Sea Ice in the Arctic, Past, Present and Future (2020).doi:10.1007/978-3-030-21301-5_3
Anthropogenic and natural drivers of a strong winter urban heat island in a typical Arctic city. Atmospheric Chemistry and Physics (ACP) 18, (2018).
Anthropogenic heating strongly amplifies the urban heat island in Arctic cities. Atmospheric Chemistry and Physics (ACP) 18, (2018).
The Arctic Surface Climate in CMIP6: Status and Developments since CMIP5. Journal of Climate 33, (2020).
Asymmetry of the surface air temperature response on climatologic heat imbalance due to differences in the planetary boundary layer height. Geophysical Research Abstracts 15, (2013).
Atmospheric heat advection in the Kara Sea region under main synoptic processes. International Journal of Climatology 39, (2018).
Climate change impacts on wind energy potential in the European domain with a focus on the Black Sea. Renewable and Sustainable Energy Reviews 81, (2017).
The Climatology of the Atmospheric Boundary Layer in Contemporary Global Climate Models. Journal of Climate 31, (2018).
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 6, (2016).
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 6, (2017).
Complementary explanation of temperature response in the lower atmosphere. Environmental Research Letters 7, (2012).
Differences in the efficacy of climate forcings explained by variations in atmospheric boundary layer depth. Nature Communications 7, (2016).
Dipole pattern of meridional atmospheric internal energy transport across the Arctic gate. Scientific Reports 12, (2022).
Diurnal asymmetry to the observed global warming. International Journal of Climatology (2015).
Driving Mechanisms of an Extreme Winter Sea Ice Breakup Event in the Beaufort Sea. Geophysical Research Letters 49, (2022).
Eurasian Cooling Patterns in the CMIP5 Climate Models. Izvestiya, Atmospheric and Oceanic Physics (2019).
Eurasian Winter Cooling: Intercomparison of Reanalyses and CMIP5 Data Sets. Atmospheric and Oceanic Science Letters 6, (2013). Last ned: outten_davy_esau_2013_eurasian_winter_cooling_intercomparison_of_reanalyses_and_cmip5_data_sets-1.pdf (11.53 MB)
Global climate models' bias in surface temperature trends and variability. Environmental Research Letters 9, (2014). Last ned: davy_2014_global_climate_models_bias_in_surface_temperature_trends_and_variability.pdf (2.02 MB)
KrigR-a tool for downloading and statistically downscaling climate reanalysis data. Environmental Research Letters 17, (2022).
