Details

Autor(en) / Beteiligte

• Schuldt, Andreas
• Liu, Xiaojuan
• Buscot, François
• Bruelheide, Helge
• Erfmeier, Alexandra
• He, Jin‐Sheng
• Klein, Alexandra‐Maria
• Ma, Keping
• Scherer‐Lorenzen, Michael
• Schmid, Bernhard
• Scholten, Thomas
• Tang, Zhiyao
• Trogisch, Stefan
• Wirth, Christian
• Wubet, Tesfaye
• Staab, Michael

Titel

Carbon–biodiversity relationships in a highly diverse subtropical forest

Ist Teil von

• Global change biology, 2023-09, Vol.29 (18), p.5321-5333

Ort / Verlag

England: Blackwell Publishing Ltd

Erscheinungsjahr

2023

Quelle

Wiley-Blackwell Journals

Beschreibungen/Notizen

• Carbon‐focused climate mitigation strategies are becoming increasingly important in forests. However, with ongoing biodiversity declines we require better knowledge of how much such strategies account for biodiversity. We particularly lack information across multiple trophic levels and on established forests, where the interplay between carbon stocks, stand age, and tree diversity might influence carbon–biodiversity relationships. Using a large dataset (>4600 heterotrophic species of 23 taxonomic groups) from secondary, subtropical forests, we tested how multitrophic diversity and diversity within trophic groups relate to aboveground, belowground, and total carbon stocks at different levels of tree species richness and stand age. Our study revealed that aboveground carbon, the key component of climate‐based management, was largely unrelated to multitrophic diversity. By contrast, total carbon stocks—that is, including belowground carbon—emerged as a significant predictor of multitrophic diversity. Relationships were nonlinear and strongest for lower trophic levels, but nonsignificant for higher trophic level diversity. Tree species richness and stand age moderated these relationships, suggesting long‐term regeneration of forests may be particularly effective in reconciling carbon and biodiversity targets. Our findings highlight that biodiversity benefits of climate‐oriented management need to be evaluated carefully, and only maximizing aboveground carbon may fail to account for biodiversity conservation requirements. We tested how multitrophic diversity relates to aboveground, belowground, and total carbon stocks in secondary, subtropical forests. Our study revealed that aboveground carbon, the key component of climate‐based management, was largely unrelated to multitrophic diversity. By contrast, belowground carbon—and in consequence total carbon stocks—emerged as a significant predictor of multitrophic diversity, moderated by tree species richness and stand age. Our findings highlight that biodiversity benefits of climate‐oriented management need to be evaluated carefully, and simply maximizing aboveground carbon may fail to account for biodiversity conservation requirements.