Sino-French Institute for Earth System Science, College of Urban and Environmental Sciences, Peking University, Beijing 100871, China.
Centre of Excellence PLECO (Plant and Vegetation Ecology), Department of Biology, University of Antwerp, Universiteitsplein 1, B-2610 Wilrijk, Belgium.
Nature. 2015 Oct 1;526(7571):104-7. doi: 10.1038/nature15402. Epub 2015 Sep 23.
Earlier spring leaf unfolding is a frequently observed response of plants to climate warming. Many deciduous tree species require chilling for dormancy release, and warming-related reductions in chilling may counteract the advance of leaf unfolding in response to warming. Empirical evidence for this, however, is limited to saplings or twigs in climate-controlled chambers. Using long-term in situ observations of leaf unfolding for seven dominant European tree species at 1,245 sites, here we show that the apparent response of leaf unfolding to climate warming (ST, expressed in days advance of leaf unfolding per °C warming) has significantly decreased from 1980 to 2013 in all monitored tree species. Averaged across all species and sites, ST decreased by 40% from 4.0 ± 1.8 days °C(-1) during 1980-1994 to 2.3 ± 1.6 days °C(-1) during 1999-2013. The declining ST was also simulated by chilling-based phenology models, albeit with a weaker decline (24-30%) than observed in situ. The reduction in ST is likely to be partly attributable to reduced chilling. Nonetheless, other mechanisms may also have a role, such as 'photoperiod limitation' mechanisms that may become ultimately limiting when leaf unfolding dates occur too early in the season. Our results provide empirical evidence for a declining ST, but also suggest that the predicted strong winter warming in the future may further reduce ST and therefore result in a slowdown in the advance of tree spring phenology.
早春叶片展开是植物对气候变暖的常见反应。许多落叶树种需要低温来解除休眠,而与变暖相关的低温减少可能会抵消叶片展开对变暖的响应。然而,这种情况的经验证据仅限于在气候控制室内的幼苗或嫩枝。本研究使用 7 种欧洲主要树种在 1245 个地点的长期原位叶片展开观测数据,结果表明,所有监测树种的叶片展开对气候变暖的明显响应(ST,用叶片每升温 1°C 提前展开的天数表示)自 1980 年以来显著下降到 2013 年。在所有物种和地点中,ST 从 1980-1994 年的 4.0±1.8 天°C(-1)平均下降到 1999-2013 年的 2.3±1.6 天°C(-1),下降了 40%。基于低温的物候模型也模拟了下降的 ST,尽管下降幅度(24-30%)比原位观测的要弱。ST 的减少可能部分归因于低温的减少。尽管如此,其他机制也可能起作用,例如“光周期限制”机制,当叶片展开日期过早发生时,该机制可能最终会成为限制因素。我们的研究结果提供了 ST 下降的经验证据,但也表明未来冬季强烈变暖可能会进一步降低 ST,从而减缓树木春季物候的提前。
