Growing‐season frost is a better predictor of tree growth than mean annual temperature in boreal mixedwood forest plantations

• Published in: Global change biology Vol. 26; no. 11; pp. 6537 - 6554
• Main Authors: Marquis, Benjamin, Bergeron, Yves, Simard, Martin, Tremblay, Francine
• Format: Journal Article
• Language: English
• Published: England Blackwell Publishing Ltd 01.11.2020
• Subjects: Annual; apical meristems; boreal forest; Boreal forests; Canada; Climate; Climate change; Climate prediction; ecotones; Forest productivity; Forests; Frost; Frost damage; frost injury; frost resistance; frost rings; Global warming; Growing season; growing‐season frosts; Growth; growth retardation; Habitat selection; Height; Meristems; Norway; Picea; Picea abies; Picea glauca; Picea mariana; Pine trees; Plantations; provenance; Seasons; Species; stem analysis; summer; sustainable forest management; Temperate forests; Temperature; tree dormancy; tree growth; Tree rings; Trees; Canada; Norway; growing-season frosts; sustainable forest management; boreal forest; tree dormancy; forest productivity; frost rings; stem analysis; Picea
• ISSN: 1354-1013; 1365-2486; 1365-2486
• DOI: 10.1111/gcb.15327

Increase in frost damage to trees due to earlier spring dehardening could outweigh the expected increase in forest productivity caused by climate warming. We quantified the impact of growing‐season frosts on the performance of three spruce species (white, black, and Norway spruce) and various seed sources with different frost tolerance in two plantations, established on both sides of the eastern Canadian boreal‐temperate forest ecotone. The objectives of this study were to determine (a) if spruce species and seed sources planted in sites far from their natural provenance would be less adapted to local site conditions, leading to increased frost damage and reduced height growth; (b) at which height above the ground growing‐season frosts ceased to damage apical meristems; and (c) if height growth was best predicted by extreme climatic events (growing‐season frosts) or by mean annual or summer temperature. At each site and for all spruce species and seed sources, we cross‐sectioned spruce trees at different heights above the ground. Tree rings were cross‐dated and screened for frost rings, which were then given a severity score based on cellular damage. Frost severity reduced height growth of all spruce species and provenances at both sites. Height growth of the non‐native Norway spruce was the most reduced by frost severity and was the smallest species at both sites. Frost caused the highest growth reduction in white spruce at the boreal mixedwood site and had the least effect on black spruce at both sites. For all spruce species, height growth was affected up to 2 m above the ground. Model selection based on corrected Akaike's information criteria (AICc) identified that minimum temperature in May was by far the best climate variable predicting tree growth (AICc weight = 1), highlighting the importance of considering extreme climatic events, which are likely to increase in the future. Growing‐season frosts reduce spruce height growth and more importantly affects white spruce compared to black spruce in plantations at the boreal‐temperate forest ecotone of western Québec. Growing‐season frosts also better predict tree height increment compared to more conventional climate variables such as mean annual temperature and mean summer temperature.