Tree diversity increases productivity through enhancing structural complexity across mycorrhizal types

Tama Ray; Benjamin M. Delory; Rémy Beugnon; Helge Bruelheide; Simone Cesarz; Nico Eisenhauer; Olga Ferlian; Julius Quosh; Goddert von Oheimb; Andreas Fichtner

doi:10.1126/sciadv.adi2362

Tree diversity increases productivity through enhancing structural complexity across mycorrhizal types

Tama Ray^*, Benjamin M. Delory, Rémy Beugnon, Helge Bruelheide, Simone Cesarz, Nico Eisenhauer, Olga Ferlian, Julius Quosh, Goddert von Oheimb^*, Andreas Fichtner^*

^*Corresponding author for this work

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

Abstract

Tree species diversity and mycorrhizal associations play a central role for forest productivity, but factors driving positive biodiversity-productivity relationships remain poorly understood. In a biodiversity experiment manipulating tree diversity and mycorrhizal associations, we examined the roles of above- and belowground processes in modulating wood productivity in young temperate tree communities and potential underlying mechanisms. We found that tree species richness, but not mycorrhizal associations, increased forest productivity by enhancing aboveground structural complexity within communities. Structurally complex communities were almost twice as productive as structurally simple stands, particularly when light interception was high. We further demonstrate that overyielding was largely explained by positive net biodiversity effects on structural complexity with functional variation in shade tolerance and taxonomic diversity being key drivers of structural complexity in mixtures. Consideration of stand structural complexity appears to be a crucial element in predicting carbon sequestration in the early successional stages of mixed-species forests.

Original language	English
Article number	eadi2362
Journal	Science advances
Volume	9
Issue number	40
DOIs	https://doi.org/10.1126/sciadv.adi2362
Publication status	Published - 2023
Externally published	Yes

Bibliographical note

Publisher Copyright:
Copyright © 2023 The Authors, some rights reserved

Funding

We are grateful to A. Koller and L. Georgi for the assistance in data collection and to M. Ehbrecht and K. Friedrich Reich for the suggestions in data analysis. We are also thankful to N. Döring for the technical assistance. This study was supported by the International Research Training Group TreeDì jointly funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) 319936945/GRK2324 and the University of Chinese Academy of Sciences (UCAS). R.B. acknowledges support by the Saxon State Ministry for Science, Culture and Tourism (SMWK), Germany (3-7304/35/6-2021/48880). The Article Processing Charges (APCs) were funded by the joint publication funds of the TU Dresden, including Carl Gustav Carus Faculty of Medicine and the SLUB Dresden, as well as the Open Access Publication Funding of the DFG Acknowledgments:W earegratefultoA.KollerandL.Georgifortheassistanceindata collectionandtoM.EhbrechtandK.FriedrichReichforthesuggestionsindataanalysis.W eare alsothankfultoN.Döringforthetechnicalassistance.Funding:Thisstudywassupportedby the International Research Tr aining Group TreeDì jointly funded by the Deutsche Forschungsgemeinschaft(DFG,GermanResearchFoundation)319936945/GRK2324andthe UniversityofChineseAcademyofSciences(UCAS).R.B.acknowledgessupportbytheSaxon StateMinistryforScience,CultureandTourism(SMWK),Germany(3-7304/35/6-2021/48880). TheArticleProcessingCharges(APCs)werefundedbythejointpublicationfundsoftheTU Dresden,includingCarlGustavCarusFa culty ofMedicineandtheSLUBDresden,aswellasthe OpenAccessPublicationFundingoftheDFGAuthorcontributions:N.E.andO.F .designed andestablishedtheexperiment.T .R., A.F ., G.v.O.,andH.B.conceivedtheideaofthestudy.T .R. collectedtheTLSdata.J.Q.collectedthetreediameterandheightdata.R.B.andS.C.collected thelightdata.T .R., A.F ., andB.M.D.analyzedthedataandcreatedthefigures.T .R. wrotethefirst draftofthemanuscriptwithsupportfromA.F .andB.M.D.Allauthorscontributedtothe discussion of the results and revisions. Competing interests: The authors declare that they havenocompetinginterests.Dataandmaterialsavailability:Alldataneededtoevaluatethe conclusionsinthepaperarepresentinthepaperand/ortheSupplementaryMaterials.Data and R codes supporting the results presented in this manuscript are available on the MyDiv Experimentdatabase(https://mydivdata.idiv.de/).

Funders	Funder number
Carl Gustav Carus Faculty of Medicine
SLUB Dresden
Saxon State Ministry for Science, Culture and Tourism
the Deutsche Forschungsgemeinschaft	319936945/GRK2324
Technische Universität Dresden
Sächsisches Staatsministerium für Wissenschaft und Kunst	3-7304/35/6-2021/48880
University of Chinese Academy of Sciences

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title = "Tree diversity increases productivity through enhancing structural complexity across mycorrhizal types",

abstract = "Tree species diversity and mycorrhizal associations play a central role for forest productivity, but factors driving positive biodiversity-productivity relationships remain poorly understood. In a biodiversity experiment manipulating tree diversity and mycorrhizal associations, we examined the roles of above- and belowground processes in modulating wood productivity in young temperate tree communities and potential underlying mechanisms. We found that tree species richness, but not mycorrhizal associations, increased forest productivity by enhancing aboveground structural complexity within communities. Structurally complex communities were almost twice as productive as structurally simple stands, particularly when light interception was high. We further demonstrate that overyielding was largely explained by positive net biodiversity effects on structural complexity with functional variation in shade tolerance and taxonomic diversity being key drivers of structural complexity in mixtures. Consideration of stand structural complexity appears to be a crucial element in predicting carbon sequestration in the early successional stages of mixed-species forests.",

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year = "2023",

doi = "10.1126/sciadv.adi2362",

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journal = "Science advances",

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AU - Ray, Tama

AU - Delory, Benjamin M.

AU - Beugnon, Rémy

AU - Bruelheide, Helge

AU - Cesarz, Simone

AU - Eisenhauer, Nico

AU - Ferlian, Olga

AU - Quosh, Julius

AU - von Oheimb, Goddert

AU - Fichtner, Andreas

PY - 2023

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AB - Tree species diversity and mycorrhizal associations play a central role for forest productivity, but factors driving positive biodiversity-productivity relationships remain poorly understood. In a biodiversity experiment manipulating tree diversity and mycorrhizal associations, we examined the roles of above- and belowground processes in modulating wood productivity in young temperate tree communities and potential underlying mechanisms. We found that tree species richness, but not mycorrhizal associations, increased forest productivity by enhancing aboveground structural complexity within communities. Structurally complex communities were almost twice as productive as structurally simple stands, particularly when light interception was high. We further demonstrate that overyielding was largely explained by positive net biodiversity effects on structural complexity with functional variation in shade tolerance and taxonomic diversity being key drivers of structural complexity in mixtures. Consideration of stand structural complexity appears to be a crucial element in predicting carbon sequestration in the early successional stages of mixed-species forests.

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Tree diversity increases productivity through enhancing structural complexity across mycorrhizal types

Abstract

Bibliographical note

Funding

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