The carbon flux from woody debris, a crucial uncertainty within global carbon-climate models, is simultaneously affected by climate, site environment and species-based variation in wood quality. In the first global analysis attempting to explicitly tease out the wood quality contribution to decomposition, we found support for our hypothesis that, under a common climate, interspecific differences in wood traits affect woody debris decomposition patterns. A meta-analysis of 36 studies from all forested continents revealed that nitrogen, phosphorus, and C : N ratio correlate with decomposition rates of angiosperms. In addition, gymnosperm wood consistently decomposes slower than angiosperm wood within common sites, a pattern that correlates with clear divergence in wood traits between the two groups. New empirical studies are needed to test whether this difference is due to a direct effect of wood trait variation on decomposer activity or an indirect effect of wood traits on decomposition microsite environment. The wood trait-decomposition results point to an important role for changes in the wood traits of dominant tree species as a driver of carbon cycling, with likely feedback to atmospheric CO(2) particularly where angiosperm species replace gymnosperms regionally. Truly worldwide upscaling of our results will require further site-based multi-species wood trait and decomposition data, particularly from low-latitude ecosystems.
The carbon flux from woody debris, a crucial uncertainty within global n class="Chemical">carbon-climate models, is simultaneously affected by climate, site environment and species-based variation in wood quality. In the first global analysis attempting to explicitly tease out the wood quality contribution to decomposition, we found support for our hypothesis that, under a common climate, interspecific differences in wood traits affect woody debris decomposition patterns. A meta-analysis of 36 studies from all forested continents revealed that nitrogen, phosphorus, and C : N ratio correlate with decomposition rates of angiosperms. In addition, gymnosperm wood consistently decomposes slower than angiosperm wood within common sites, a pattern that correlates with clear divergence in wood traits between the two groups. New empirical studies are needed to test whether this difference is due to a direct effect of wood trait variation on decomposer activity or an indirect effect of wood traits on decomposition microsite environment. The wood trait-decomposition results point to an important role for changes in the wood traits of dominant tree species as a driver of carbon cycling, with likely feedback to atmospheric CO(2) particularly where angiosperm species replace gymnosperms regionally. Truly worldwide upscaling of our results will require further site-based multi-species wood trait and decomposition data, particularly from low-latitude ecosystems.
Authors: Anne D Bjorkman; Isla H Myers-Smith; Sarah C Elmendorf; Signe Normand; Nadja Rüger; Pieter S A Beck; Anne Blach-Overgaard; Daan Blok; J Hans C Cornelissen; Bruce C Forbes; Damien Georges; Scott J Goetz; Kevin C Guay; Gregory H R Henry; Janneke HilleRisLambers; Robert D Hollister; Dirk N Karger; Jens Kattge; Peter Manning; Janet S Prevéy; Christian Rixen; Gabriela Schaepman-Strub; Haydn J D Thomas; Mark Vellend; Martin Wilmking; Sonja Wipf; Michele Carbognani; Luise Hermanutz; Esther Lévesque; Ulf Molau; Alessandro Petraglia; Nadejda A Soudzilovskaia; Marko J Spasojevic; Marcello Tomaselli; Tage Vowles; Juha M Alatalo; Heather D Alexander; Alba Anadon-Rosell; Sandra Angers-Blondin; Mariska Te Beest; Logan Berner; Robert G Björk; Agata Buchwal; Allan Buras; Katherine Christie; Elisabeth J Cooper; Stefan Dullinger; Bo Elberling; Anu Eskelinen; Esther R Frei; Oriol Grau; Paul Grogan; Martin Hallinger; Karen A Harper; Monique M P D Heijmans; James Hudson; Karl Hülber; Maitane Iturrate-Garcia; Colleen M Iversen; Francesca Jaroszynska; Jill F Johnstone; Rasmus Halfdan Jørgensen; Elina Kaarlejärvi; Rebecca Klady; Sara Kuleza; Aino Kulonen; Laurent J Lamarque; Trevor Lantz; Chelsea J Little; James D M Speed; Anders Michelsen; Ann Milbau; Jacob Nabe-Nielsen; Sigrid Schøler Nielsen; Josep M Ninot; Steven F Oberbauer; Johan Olofsson; Vladimir G Onipchenko; Sabine B Rumpf; Philipp Semenchuk; Rohan Shetti; Laura Siegwart Collier; Lorna E Street; Katharine N Suding; Ken D Tape; Andrew Trant; Urs A Treier; Jean-Pierre Tremblay; Maxime Tremblay; Susanna Venn; Stef Weijers; Tara Zamin; Noémie Boulanger-Lapointe; William A Gould; David S Hik; Annika Hofgaard; Ingibjörg S Jónsdóttir; Janet Jorgenson; Julia Klein; Borgthor Magnusson; Craig Tweedie; Philip A Wookey; Michael Bahn; Benjamin Blonder; Peter M van Bodegom; Benjamin Bond-Lamberty; Giandiego Campetella; Bruno E L Cerabolini; F Stuart Chapin; William K Cornwell; Joseph Craine; Matteo Dainese; Franciska T de Vries; Sandra Díaz; Brian J Enquist; Walton Green; Ruben Milla; Ülo Niinemets; Yusuke Onoda; Jenny C Ordoñez; Wim A Ozinga; Josep Penuelas; Hendrik Poorter; Peter Poschlod; Peter B Reich; Brody Sandel; Brandon Schamp; Serge Sheremetev; Evan Weiher Journal: Nature Date: 2018-09-26 Impact factor: 49.962
Authors: Johannes H C Cornelissen; Ute Sass-Klaassen; Lourens Poorter; Koert van Geffen; Richard S P van Logtestijn; Jurgen van Hal; Leo Goudzwaard; Frank J Sterck; René K W M Klaassen; Grégoire T Freschet; Annemieke van der Wal; Henk Eshuis; Juan Zuo; Wietse de Boer; Teun Lamers; Monique Weemstra; Vincent Cretin; Rozan Martin; Jan den Ouden; Matty P Berg; Rien Aerts; Godefridus M J Mohren; Mariet M Hefting Journal: Ambio Date: 2012 Impact factor: 5.129
Authors: Markus Reichstein; Michael Bahn; Miguel D Mahecha; Jens Kattge; Dennis D Baldocchi Journal: Proc Natl Acad Sci U S A Date: 2014-09-15 Impact factor: 11.205