Tree diversity shapes the spectral signature of light transmittance in developing forests

Laura J. Williams; Kyle R. Kovach; J. Antonio Guzmán Q.; Artur Stefanski; Raimundo Bermudez; Ethan E. Butler; Domitille Coq--Etchegaray; Catherine Glenn-Stone; Peter Hajek; Johanna Klama; Belinda E. Medlyn; Christian Messier; Aboubakr Moradi; Alain Paquette; Maria H. Park; Michael Scherer-Lorenzen; Philip A. Townsend; Peter B. Reich; Jeannine Cavender-Bares; Meredith C. Schuman

doi:10.1002/ecy.70032

Tree diversity shapes the spectral signature of light transmittance in developing forests

Laura J. Williams, Kyle R. Kovach, J. Antonio Guzmán Q., Artur Stefanski, Raimundo Bermudez, Ethan E. Butler, Domitille Coq--Etchegaray, Catherine Glenn-Stone, Peter Hajek, Johanna Klama, Belinda E. Medlyn, Christian Messier, Aboubakr Moradi, Alain Paquette, Maria H. Park, Michael Scherer-Lorenzen, Philip A. Townsend, Peter B. Reich, Jeannine Cavender-Bares, Meredith C. Schuman

Research output: Contribution to journal › Article › peer-review

Abstract

Greater tree diversity often increases forest productivity by increasing the fraction of light captured and the effectiveness of light use at the community scale. However, light may shape forest function not only as a source of energy or a cause of stress but also as a context cue: Plant photoreceptors can detect specific wavelengths of light, and plants use this information to assess their neighborhoods and adjust their patterns of growth and allocation. These cues have been well documented in laboratory studies, but little studied in diverse forests. Here, we examined how the spectral profile of light (350–2200 nm) transmitted through canopies differs among tree communities within three diversity experiments on two continents (200 plots each planted with one to 12 tree species, amounting to roughly 10,000 trees in total), laying the groundwork for expectations about how diversity in forests may shape light quality with consequences for forest function. We hypothesized—and found—that the species composition and diversity of tree canopies influenced transmittance in predictable ways. Canopy transmittance—in total and in spectral regions with known biological importance—principally declined with increasing leaf area per ground area (LAI) and, in turn, LAI was influenced by the species composition and diversity of communities. For a given LAI, broadleaved angiosperm canopies tended to transmit less light with lower red-to-far-red ratios than canopies of needle-leaved gymnosperms or angiosperm-gymnosperm mixtures. Variation among communities in the transmittance of individual leaves had a minor effect on canopy transmittance in the visible portion of the spectrum but contributed beyond this range along with differences in foliage arrangement. Transmittance through mixed species canopies often deviated from expectations based on monocultures, and this was only partly explained by diversity effects on LAI, suggesting that diversity effects on transmittance also arose through shifts in the arrangement and optical properties of foliage. We posit that differences in the spectral profile of light transmitted through diverse canopies serve as a pathway by which tree diversity affects some forest ecosystem functions.

Original language	English (US)
Article number	e70032
Journal	Ecology
Volume	106
Issue number	3
DOIs	https://doi.org/10.1002/ecy.70032
State	Published - Mar 2025

Bibliographical note

Publisher Copyright:
© 2025 The Author(s). Ecology published by Wiley Periodicals LLC on behalf of The Ecological Society of America.

Keywords

IDENT
biodiversity–ecosystem function
canopy structure
leaf optical properties
light quality cues
neighborhood interactions
photoreceptors
spectral canopy transmittance

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10.1002/ecy.70032

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Williams, L. J., Kovach, K. R., Guzmán Q., J. A., Stefanski, A., Bermudez, R., Butler, E. E., Coq--Etchegaray, D., Glenn-Stone, C., Hajek, P., Klama, J., Medlyn, B. E., Messier, C., Moradi, A., Paquette, A., Park, M. H., Scherer-Lorenzen, M., Townsend, P. A., Reich, P. B., Cavender-Bares, J., & Schuman, M. C. (2025). Tree diversity shapes the spectral signature of light transmittance in developing forests. Ecology, 106(3), Article e70032. https://doi.org/10.1002/ecy.70032

Williams, LJ, Kovach, KR, Guzmán Q., JA, Stefanski, A , Bermudez, R, Butler, EE, Coq--Etchegaray, D, Glenn-Stone, C, Hajek, P, Klama, J, Medlyn, BE, Messier, C, Moradi, A, Paquette, A, Park, MH, Scherer-Lorenzen, M, Townsend, PA, Reich, PB , Cavender-Bares, J & Schuman, MC 2025, 'Tree diversity shapes the spectral signature of light transmittance in developing forests', Ecology, vol. 106, no. 3, e70032. https://doi.org/10.1002/ecy.70032

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abstract = "Greater tree diversity often increases forest productivity by increasing the fraction of light captured and the effectiveness of light use at the community scale. However, light may shape forest function not only as a source of energy or a cause of stress but also as a context cue: Plant photoreceptors can detect specific wavelengths of light, and plants use this information to assess their neighborhoods and adjust their patterns of growth and allocation. These cues have been well documented in laboratory studies, but little studied in diverse forests. Here, we examined how the spectral profile of light (350–2200 nm) transmitted through canopies differs among tree communities within three diversity experiments on two continents (200 plots each planted with one to 12 tree species, amounting to roughly 10,000 trees in total), laying the groundwork for expectations about how diversity in forests may shape light quality with consequences for forest function. We hypothesized—and found—that the species composition and diversity of tree canopies influenced transmittance in predictable ways. Canopy transmittance—in total and in spectral regions with known biological importance—principally declined with increasing leaf area per ground area (LAI) and, in turn, LAI was influenced by the species composition and diversity of communities. For a given LAI, broadleaved angiosperm canopies tended to transmit less light with lower red-to-far-red ratios than canopies of needle-leaved gymnosperms or angiosperm-gymnosperm mixtures. Variation among communities in the transmittance of individual leaves had a minor effect on canopy transmittance in the visible portion of the spectrum but contributed beyond this range along with differences in foliage arrangement. Transmittance through mixed species canopies often deviated from expectations based on monocultures, and this was only partly explained by diversity effects on LAI, suggesting that diversity effects on transmittance also arose through shifts in the arrangement and optical properties of foliage. We posit that differences in the spectral profile of light transmitted through diverse canopies serve as a pathway by which tree diversity affects some forest ecosystem functions.",

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Tree diversity shapes the spectral signature of light transmittance in developing forests

Abstract

Bibliographical note

Keywords

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