Summary At high elevations, tree saplings and shrubs are usually protected by mid‐winter snow cover, although climate change is expected to extend the snow‐free (SF) period. Exposure to winter drought, freeze–thaw events and freezing temperatures will therefore increase, inducing damages to the hydraulic system and to living cells, resulting in reduced growth and increased mortality. A snow removal experiment was carried out at 1700 m. above sea level on saplings of five different species ( Acer pseudoplatanus , Juniperus communis , Larix decidua , Picea abies and Sorbus aucuparia ). Stem diameter was continuously monitored and compared with spring hydraulic conductivity (PLC spring ), living cell mortality (PLD spring ), nonstructural carbohydrates (NSCs), growth and survival rates. Under SF conditions, saplings had higher PLC spring and higher PLD spring , and thus experienced greater winter dehydration, resulting in lower growth compared with snow‐covered saplings. Summer mortality was strongly correlated with PLC spring and PLD spring . These two key ecophysiological parameters predicted the risk of mortality in all species, whereas only PLD spring reduced growth. By monitoring stem diameter during winter, we have defined indices to quantify resistance and recovery of woody plants under increased frost pressure. Recovery strategies such as resprouting or embolism repair were critical for survival, highlighting the potential vulnerability of saplings to climate change at high elevations.
Charra‐Vaskou et al. (Tue,) studied this question.