Abstract
Dormant seeds that require long periods of cold stratification to become germinable may be most sensitive to increases in winter temperatures caused by anthropogenic climate change. In this study, we used outdoor plots with infrared heaters to simulate the effects of projected winter warming (+6 °C) for Canada’s Acadian Forest Region and compared seed germination success of tree species with varying stratification requirements. We evaluated four seedlots each of balsam fir (Abies balsamea (L.) Mill.), red spruce (Picea rubens Sarg.), white pine (Pinus strobus L.), red maple (Acer rubrum L.), sugar maple (Acer saccharum Marshall), and yellow birch (Betula alleghaniensis Britton). Three central findings emerged from this study: (i) none of the tested species were significantly affected by warming; (ii) the random effect of seedlot explained more variation in germination success of deciduous species than it did for conifers; and (iii) balsam fir seedlots exhibited considerable differences in their response to warming, implying intraspecific variation in depth of dormancy. These results suggest seed germination success of the tested tree species may not be impeded by their individual seed characteristics under the magnitude of winter warming projected over the coming century in our study area.
Highlights
Evaluating the effects of climate change on forest stand regeneration is of increasing importance to forest managers and stakeholders
The results of our study do not support our first hypothesis that germination success of seeds that require long durations of cold stratification will decrease with warming, but rather suggest the magnitude of winter warming projected for the Acadian Forest Region under Representative Concentration Pathway 8.5 (RCP) 8.5 may not affect germination success
While snow depth is predicted to decrease with winter warming along with the insulative properties it provides, reductions in soil temperature and the consequential impact on seed germination success may not be as severe as past field studies suggest
Summary
Evaluating the effects of climate change on forest stand regeneration is of increasing importance to forest managers and stakeholders. Under the same climate change scenario, mean winter temperature is expected to increase by 6°C (McKenney et al 2013) This intensity of winter warming will reduce snow cover period and depth, and spring soil moisture (Houle et al 2012), which could have significant impacts on ecological processes that control stand regeneration (Campbell et al 2005). The successful germination of some tree species requires a particular range of environmental conditions to relieve seed dormancy to become germinable (Walck et al 2011). Variations in these conditions may affect regeneration and establishment of these species, especially in natural stands
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