Late spring frosts (LSF) pose ecological and economic risks, yet their changing frequency and extent under climate warming remain unclear. Using 1220 observations from 304 French oak populations (1997–2021), we developed and validated a model to simulate LSF damage. Our results reveal a long-term decline in LSF frequency (-0.22% yr⁻¹) and extent (-0.34% yr⁻¹) from 1961 to 2021, driven by a faster advancement of the last frost day (-0.28 days yr⁻¹) than budburst (-0.21 days yr⁻¹). However, regional variations emerge, with continental areas experiencing increased frost damage extent despite reduced frequency. These findings underscore the importance of considering both LSF frequency and extent when assessing frost risks in a warming climate, providing a comprehensive framework for future ecological and economic evaluations of LSF impacts.

We developed process-based tree phenology models for four subtropical tree species, and for the first time for these trees, we based the model development on explicit experimental work particularly designed to address the processes being modelled. For all the four species, a model of seedling leafout was developed, and for Torreya grandis, a model for female flowering in adult trees was additionally developed. The models generally showed reasonable accuracy when tested against two sources of independent data. In scenario simulations, the models projected an advanced spring phenology under climatic warming for 2020 – 2100. For the leafout of seedlings, the advancing rates varied between 4.7 and 5.9 days per one oC warming, with no major differences found between the climatic scenarios RCP4.5 and RCP8.5. For Torreya flowering, less advancing was projected, and the projected advancing per one oC warming was less for RCP8.5 (0.9 days / oC) than for RCP4.5 (2.3 days / oC). The low advancing rates of Torreya flowering were caused by reduced chilling under the warming climate and by the particular temperature responses found for Torreya flowering. These findings highlight the need to base the model development on explicit experiments particularly designed to address the process modelled.