Timing of forest fine root production advances with reduced snow cover in northern Japan: implications for climate-induced change in understory and overstory competition

To investigate the effect of reduced snow cover on fine root dynamics in a cool-temperate forest in northern Japan because of decreases in snowfall at high latitudes due to global warming, we monitored root length, production, and mortality before and after snow removal with an in-ground root scanne...

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Bibliographic Details
Published in:Oecologia 2021-05, Vol.196 (1), p.263-273
Main Authors: Fukuzawa, Karibu, Tateno, Ryunosuke, Ugawa, Shin, Watanabe, Tsunehiro, Hosokawa, Nanae, Imada, Shogo, Shibata, Hideaki
Format: Article
Language:English
Subjects:
Bamboo
Biogeochemistry
Biomedical and Life Sciences
Carbon cycle
Climate change
Dynamics
Ecology
Ecosystems
Forest ecology
Forest ecosystems
Forests
Freezing
Global Change Ecology–Original Research
Global warming
Growing season
Health aspects
Hydrology/Water Resources
Life Sciences
Methylene blue
Mortality
Net Primary Productivity
Oak
Photosynthesis
Plant Sciences
Primary production
Production management
Removal
Snow
Snow cover
Snow removal
Species
Temperate forests
Terrestrial ecosystems
Understory
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Summary:To investigate the effect of reduced snow cover on fine root dynamics in a cool-temperate forest in northern Japan because of decreases in snowfall at high latitudes due to global warming, we monitored root length, production, and mortality before and after snow removal with an in-ground root scanner. We measured root dynamics of both overstory deciduous oak ( Quercus crispula ) and understory evergreen dwarf bamboo ( Sasa nipponica ), the two major species in the forest. Snow removal advanced the timing of peak root production by a month both in total and in Sasa , but not in oak. There was a significant interaction between snow removal and plant form on root production; this indicates that enhanced Sasa root production following snow removal might increase its ability to compete with oak. In contrast, snow removal did not enhance root mortality, suggesting that the roots of these species tolerate soil freezing. The earlier snow disappearance in the snow removal plot expanded the growing season in Sasa . We speculate that this change in the understory environment would advance the timing of root production by Sasa by extending the photosynthetic period in spring. We propose that different responses of root production to reduced snow cover between the two species would change the competitive interactions of overstory and understory vegetation, influencing net primary production and biogeochemistry (e.g., carbon and nitrogen cycles) in the forest ecosystem.
ISSN:0029-8549
1432-1939
DOI:10.1007/s00442-021-04914-x