AbstractThe flux of moist static energy into the polar regions plays a key role in the energy budget and climate of the polar regions. While usually studied from a vertically integrated perspective (Fwall), this analysis examines its vertical structure, using the NASA-MERRA-2 reanalysis to compute climatological and anomalous fluxes of sensible, latent, and potential energy across 70°N and 65°S for the period 1980–2016. The vertical structure of the climatological flux is bimodal, with peaks in the middle to lower troposphere and middle to upper stratosphere. The near-zero flux at the tropopause defines the boundary between stratospheric (Fstrat) and tropospheric (Ftrop) contributions toFwall. Especially at 70°N,Fstratis found to be important to the climatology and variability ofFwall, contributing 20.9 W m−2toFwall(19% ofFwall) during the winter and explaining 23% of the variance ofFwall. During winter, an anomalous poleward increase inFstratpreceding a sudden stratospheric warming is followed by an increase in outgoing longwave radiation anomalies, with little influence on the surface energy budget of the Arctic. Conversely, a majority of the energy input by an anomalous poleward increase inFtropgoes toward warming the Arctic surface. Overall,Ftropis found to be a better metric thanFwallfor evaluating the influence of atmospheric circulations on the Arctic surface climate.