Biblio
Filters: Author is Esau, Igor [Clear All Filters]
Vertical structure of recent Arctic warming from observed data and reanalysis products. EGU General Assembly 11, (2009).
Vertical structure of recent Arctic warming from observed data and reanalysis products. EOS Transactions 89, (2008).
Looking for remote air temperature signal in the Arctic. EGU General ASsembly, 13-18 April, Vienna, Austria, Geophysical Research Abstracts, 10, EGU2008-A-10967 (2008).
Vertical structure of recent arctic warming from observed data and reanalysis products. Climatic Change 111, (2012).
Vertical structure of recent Arctic warming from observed data and reanalysis products. International Polar Year Science Conference (2010).
MEGAPOLI: concept of multi-scale modelling of megacity impact on air quality and climate. Advances in Science & Research 4, (2010). Abstract
Review and assessment of latent and sensible heat flux accuracy over the global oceans. Remote Sensing of Environment 201, (2017).
Sensitivity of simulated wintertime Arctic atmosphere to vertical resolution in the ARPEGE/IFS model. Climate Dynamics 30, 687-701 (2008). Abstract
Sensitivity of simulated wintertime Arctic atmosphere to vertical resolution in the ARPEGE/IFS model. Open science conference Polar Dynamics: Monitoring, Understanding, and Prediction, August 29-31, Bergen, Norway (2007).
Stably Stratified Flows: A Model with No Ri(Cr)*. Journal of Atmospheric Sciences 65, 2437-2447 (2008).
Total cloudiness over the Arctic in winter: an intercomparison of different climatologies, an assessment of inter-annual variability and connection with surface air temperature. Geophysical Research Abstracts 15, (2013).
Surface air temperature variability in global climate models. Atmospheric Science Letters 15, (2014). Abstract
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).
Differences in the efficacy of climate forcings explained by variations in atmospheric boundary layer depth. Nature Communications 7, (2016).
Surface air temperature changes in the high-latitude boundary layer. Report Series in Aerosol Science 180, (2016).
Global climate models' bias in surface temperature trends and variability. Environmental Research Letters 9, (2014).
An improved parameterization of turbulent exchange coefficients accounting for the non-local effect of large eddies. Annales Geophysicae 10, 1-10 (2004).
Simulation of the Largest Coherent Vortices (Rolls) in the Ekman Boundary Layer. Journal of Vortex Science and Technology 1, (2012).