Abstract
In Northern Europe, poplars (Populus) can provide biomass for energy and material use, but most available clones were developed for lower latitudes and are unlikely to be well adapted to higher latitudes, even under warmer climates. We thus need to understand how clones respond to climatic conditions and photoperiod, and how these responses can be predicted. We answer these questions exploiting leaf phenological data of Populus clones, grown in six sites across the Baltic region, in Northern Europe, for 2 years with contrasting climatic conditions. Regarding the effects of climatic conditions and photoperiod, within each site, higher temperatures advanced the timing and enhanced the speed of spring and autumn phenology, but reduced the effective growing season length. Across sites, latitude affected the timing of spring and autumn phenology, the speed of spring phenology, and the effective growing season length; clone affected only the timing of phenology. Regarding the predictability of clone response to growing conditions, the growing degree day (GDD) model could not predict spring phenology, because the growing degree day threshold for a specific phenological stage was not only clone-, but also latitude- and year-specific. Yet, this GDD threshold allowed a robust ranking of clones across sites and years, thus providing a tool to determine the relative differences across clones, independently of latitude and temperature. A similar, but not as strong, pattern was observed in the timing of spring and autumn phenological stages. Hence, while prediction of spring phenology remains elusive, the ranking of clones based on observations of their phenology in a single location can provide useful indications on the clones’ relative performance under different latitudes and climates.
Highlights
The commercial demand for woody biomass is expected to grow in the future
The analyses focused on different aspects characterizing spring and autumn phenology and duration of the effective growing season, and : the fitted parameters of Eq 1 for spring (t50, bb and kbb) and autumn (t50, ls and kls); the resulting length of the effective growing season; and the accumulated growing degree days at spring phenology score 3 (GDD*3 )
The growing degree days cumulated at bud break reference score 3, GDD*3, was larger in spring 2018 than 2017 (Fig. 4)
Summary
The commercial demand for woody biomass is expected to grow in the future. Fast-growing Populus species (poplars and aspens) grown in short- or medium-rotation forestry provide an alternative to biomass from conventional forests, as they contribute to efficient and sustainable land use and provide a flexible final product for use in material or energy production [1]. To ensure sustained and stable productivity, Phenology plays a pivotal role in survival and productivity of deciduous species, including Populus spp. While all aspects of plant activity are affected by growing conditions, leaf phenology defines the period during which carbon fixation and growth can occur. The timing of leaf phenology transitions [including bud break, bud set, leaf senescence and shedding; 6] needs to balance the risks of plant organs being exposed to harsh winter conditions, with the opportunity to exploit optimal conditions for carbon fixation [and growth and reproduction; 7, 8–12]. While conservative strategies (late bud break and early autumn phenology) can limit the exposure to damaging low temperatures [13, 14], such a risk-averse strategy reduces the length of the effective growing season and can curtail plant growth, competitive ability, and final biomass production.
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