Abstract. Low-level clouds strongly influence the Arctic surface energy budget and hydrological cycle, yet their representation in climate models remains challenging due to limited observations and complex interactions between local processes and large-scale conditions. This study analyzes eight years (2007–2016) of active remote sensing observations from CALIPSO and CloudSat to investigate the regional and seasonal distribution of four types of low-level clouds (between clutter height and 3000 m above ground level): warm liquid, ice-only, mixed-phase clouds (MPCs), and unglaciated supercooled liquid clouds (USLCs). 48 % of Arctic clouds occur at low altitudes. Statistical analysis of cloud-type occurrence shows that MPCs account for 17 %, ice-only clouds for 21 %, and USLCs for 8 %. This study provides a satellite-based assessment of USLCs over the Arctic, revealing occurrences of up to 20 % over marine regions during transition seasons. Multiple linear regressions are used to quantify the influence of key environmental drivers on the cloud type distribution. MPCs are linked to dynamically unstable conditions such as marine cold-air outbreaks, especially over open sea regions. USLCs preferentially develop under stable and relatively dry mid-tropospheric environments compared to ice clouds. Cloud–surface coupling shows that, on average, 17 % of low-level clouds are coupled to the surface. In winter, USLCs are more frequently coupled with the open ocean than with sea ice, emphasizing the strong thermodynamic control of the underlying surface. Ice-containing clouds are more frequently surface-coupled than USLCs. These results provide new insight into Arctic cloud-phase variability and offer guidance for improving their representation in large-scale models.
Dziduch et al. (Mon,) studied this question.