Patterns, dynamics and drivers of alpine treelines and shrublines

Alpine treelines and shrublines are highly sensitive to environmental change. In this Review, we summarize their global patterns and trends, underlying mechanisms and impacts. Continental alpine treeline and shrubline elevations are highest at mid-latitudes, declining towards the Equator and poles. Shrublines are typically 335 m higher than collocated treelines owing to morphological differences. The mass-elevation effect, whereby larger mountain masses retain more heat, largely governs this distribution. Indeed, temperature is a key factor determining ecotone elevation. For example, tree growth near the alpine treeline begins at 0.9 °C and continues as long as the average temperature during the growing season exceeds 6.4 °C for a minimum of 94 days.  Water availability is also important, with 51% of treelines exposed to drought stress. Overall, between 1901 and 2021, alpine treelines and shrublines have shifted to higher elevations at an average rate of 0.40 and 0.49 m yr−1, respectively, with shift rates at high-latitude sites exceeding those at lower latitudes. Species interactions (either through facilitation or competition) and disturbances complicate these trends. As a result, treeline shift lags behind climate warming by at least 50 years, with drought stress, species interactions and disturbance becoming increasingly important as warming continues. The consequences of treeline and shrubline advance include reduced soil carbon storage, biodiversity decline, and reduced surface albedo. Future research should prioritize extended field monitoring to enhance projection accuracy of ecotone dynamics and associated climate feedbacks across local to global scales. Alpine treelines and shrublines are advancing to higher elevations in the context of warming. This Review synthesizes global trends in ecotone dynamics, explores the underlying drivers and mechanisms, and considers the consequences to alpine regions.