Evaluating structural and compositional canopy characteristics to predict the light-demand signature of the forest understorey in mixed, semi-natural temperate forests

6533b873fe1ef96bd12d56dd

RESEARCH PRODUCT

Evaluating structural and compositional canopy characteristics to predict the light-demand signature of the forest understorey in mixed, semi-natural temperate forests

Déborah Closset-kopp Martin Kopecký Martin Kopecký Monika Wulf Guntis Brumelis Steffi Heinrichs Werner Härdtle Jan Den Ouden Dries Landuyt Jörg Brunet Haben Blondeel Radim Hédl František Máliš Kris Verheyen Simon M. Smart Guillaume Decocq Wolfgang Schmidt Emiel De Lombaerde Michael P. Perring Michael P. Perring Ilze Liepiņa Martin Macek Karol Ujházy Thilo Heinken Bogdan Jaroszewicz Sybryn L. Maes Leen Depauw

subject

0106 biological sciences Canopy [SDV]Life Sciences [q-bio]DIVERSITY Atmospheric sciences 01 natural sciences canopy closure shade-casting ability Basal area SOLAR-RADIATION TRANSMITTANCE herb layer light availability Environmental planning Ecology Policy and Law Temperate forest Forestry Vegetation Understory PE&RC COMMUNITY basal area Ecosystems Research light transmittance Life Sciences & Biomedicine Temperate rainforest Monitoring Environmental Sciences & Ecology Management Monitoring Policy and Law 010603 evolutionary biology Ecology and Environment Ellenberg indicator values understorey Forest ecology GAP FORMATION MANAGEMENT Bosecologie en Bosbeheer /dk/atira/pure/core/keywords/biology Nature and Landscape Conservation Forest floor Science & Technology /dk/atira/pure/core/keywords/557265479 Plant Sciences SEEDLING SURVIVAL 15. Life on land COVER Forest Ecology and Forest Management LAYER Earth and Environmental Sciences temperate forest canopy cover Environmental science VEGETATION 010606 plant biology & botany RESPONSES

description

Questions: Light availability at the forest floor affects many forest ecosystem processes, and is often quantified indirectly through easy-to-measure stand characteristics. We investigated how three such characteristics, basal area, canopy cover and canopy closure, were related to each other in structurally complex mixed forests. We also asked how well they can predict the light-demand signature of the forest understorey (estimated as the mean Ellenberg indicator value for light [“EIVLIGHT”] and the proportion of “forest specialists” [“%FS”] within the plots). Furthermore, we asked whether accounting for the shade-casting ability of individual canopy species could improve predictions of EIVLIGHT and %FS. Location: A total of 192 study plots from nineteen temperate forest regions across Europe. Methods: In each plot, we measured stand basal area (all stems >7.5 cm diameter), canopy closure (with a densiometer) and visually estimated the percentage cover of all plant species in the herb (<1 m), shrub (1–7 m) and tree layer (>7 m). We used linear mixed-effect models to assess the relationships between basal area, canopy cover and canopy closure. We performed model comparisons, based on R2 and the Akaike Information Criterion (AIC), to assess which stand characteristics can predict EIVLIGHT and %FS best, and to assess whether canopy shade-casting ability can significantly improve model fit. Results: Canopy closure and cover were weakly related to each other, but showed no relation with basal area. For both EIVLIGHT and %FS, canopy cover was the best predictor. Including the share of high-shade-casting species in both the basal-area and cover models improved the model fit for EIVLIGHT, but not for %FS. Conclusions: The typically expected relationships between basal area, canopy cover and canopy closure were weak or even absent in structurally complex mixed forests. In these forests, easy-to-measure structural canopy characteristics were poor predictors of the understorey light-demand signature, but accounting for compositional characteristics could improve predictions.

year	journal	country	edition	language
2020-10-18	Applied Vegetation Science

10.1111/avsc.12532 https://doi.org/10.1111/avsc.12532