Department of Geological and Atmospheric Sciences, Iowa State University, Ames, IA, USA.
Environmental Sciences Division and Climate Change Science Institute, Oak Ridge National Laboratory, Oak Ridge, TN, USA.
Glob Chang Biol. 2021 Jun;27(12):2914-2927. doi: 10.1111/gcb.15575. Epub 2021 Mar 16.
Vegetation phenology in spring has substantially advanced under climate warming, consequently shifting the seasonality of ecosystem process and altering biosphere-atmosphere feedbacks. However, whether and to what extent photoperiod (i.e., daylength) affects the phenological advancement is unclear, leading to large uncertainties in projecting future phenological changes. Here we examined the photoperiod effect on spring phenology at a regional scale using in situ observation of six deciduous tree species from the Pan European Phenological Network during 1980-2016. We disentangled the photoperiod effect from the temperature effect (i.e., forcing and chilling) by utilizing the unique topography of the northern Alps of Europe (i.e., varying daylength but uniform temperature distribution across latitudes) and examining phenological changes across latitudes. We found prominent photoperiod-induced shifts in spring leaf-out across latitudes (up to 1.7 days per latitudinal degree). Photoperiod regulates spring phenology by delaying early leaf-out and advancing late leaf-out caused by temperature variations. Based on these findings, we proposed two phenological models that consider the photoperiod effect through different mechanisms and compared them with a chilling model. We found that photoperiod regulation would slow down the advance in spring leaf-out under projected climate warming and thus mitigate the increasing frost risk in spring that deciduous forests will face in the future. Our findings identify photoperiod as a critical but understudied factor influencing spring phenology, suggesting that the responses of terrestrial ecosystem processes to climate warming are likely to be overestimated without adequately considering the photoperiod effect.
植被物候在气候变暖的影响下已经大幅提前,这导致了生态系统过程的季节性发生变化,并改变了生物圈-大气的反馈。然而,光照时间(即白昼长度)是否以及在多大程度上影响物候提前,目前还不清楚,这导致了对未来物候变化的预测存在很大的不确定性。在这里,我们利用欧洲泛植物物候网络 1980-2016 年期间对六种落叶树种的实地观测,在区域尺度上研究了光照时间对春季物候的影响。我们通过利用欧洲北部阿尔卑斯山的独特地形(即不同的白昼长度,但纬度间温度分布均匀),并在纬度间检查物候变化,从而将光照时间的影响与温度的影响(即强迫和冷胁迫)分离开来。我们发现,光照时间在纬度间引起了显著的春季物候变化(每个纬度度可达 1.7 天)。光照时间通过延迟由温度变化引起的早期展叶和提前晚期展叶来调节春季物候。基于这些发现,我们提出了两个物候模型,它们通过不同的机制考虑了光照时间的影响,并将其与冷胁迫模型进行了比较。我们发现,在预测的气候变暖下,光照时间的调节将减缓春季展叶的提前,从而减轻未来落叶林在春季将面临的日益增加的霜害风险。我们的研究结果确定了光照时间作为影响春季物候的一个关键但研究不足的因素,这表明,如果没有充分考虑光照时间的影响,陆地生态系统过程对气候变暖的响应可能被高估。
