Independent effects of tree diversity on aboveground and soil carbon pools after six years of experimental afforestation.

IF 4.3 2区环境科学与生态学 Q1 ECOLOGY

Ecological Applications Pub Date : 2024-10-15 DOI:10.1002/eap.3042

Reb L Bryant,Shan Kothari,Jeannine Cavender-Bares,Stephanie J Curran,Jake J Grossman,Sarah E Hobbie,Charlotte Nash,Grace C Neumiller,Craig R See

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引用次数: 0

Abstract

Planting diverse forests has been proposed as a means to increase long-term carbon (C) sequestration while providing many co-benefits. Positive tree diversity-productivity relationships are well established, suggesting more diverse forests will lead to greater aboveground C sequestration. However, the effects of tree diversity on belowground C storage have the potential to either complement or offset aboveground gains, especially during early stages of afforestation when potential exists for large losses in soil C due to soil decomposition. Thus, experimental tests of the effects of planted tree biodiversity on changes in whole-ecosystem C balance are needed. Here, we present changes in above- and belowground C pools 6 years after the initiation of the Forests and Biodiversity experiment (FAB1), consisting of high-density plots of one, two, five, or 12 tree species planted in a common garden. The trees included a diverse range of native species, including both needle-leaf conifer and broadleaf angiosperm species, and both ectomycorrhizal and arbuscular mycorrhizal species. We quantified the effects of species richness, phylogenetic diversity, and functional diversity on aboveground woody C, as well as on mineral soil C accumulation, fine root C, and soil aggregation. Surprisingly, changes in aboveground woody C pools were uncorrelated to changes in mineral soil C pools, suggesting that variation in soil C accumulation was not driven by the quantity of plant litter inputs. Aboveground woody C accumulation was strongly driven by species and functional identity; however, plots with higher species richness and functional diversity accumulated more C in aboveground wood than expected based on monocultures. We also found weak but significant effects of tree species richness, identity, and mycorrhizal type on soil C accumulation. To assess the role of the microbial community in mediating these effects, we further compared changes in soil C pools to phospholipid fatty acid (PLFA) profiles. Soil C pools and accumulation were more strongly correlated with specific microbial clades than with total microbial biomass or plant diversity. Our results highlight rapidly emerging and microbially mediated effects of tree biodiversity on soil C storage in the early years of afforestation that are independent of gains in aboveground woody biomass.

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实验造林六年后，树木多样性对地上和土壤碳库的独立影响。

种植多样性森林被认为是增加长期碳（C）螯合的一种手段，同时还能带来许多共同效益。树木多样性与生产率之间的正相关关系已得到充分证实，这表明更多样化的森林将带来更多的地上碳固存。然而，树木多样性对地下碳储量的影响有可能补充或抵消地上碳储量的增加，尤其是在植树造林的早期阶段，由于土壤分解，土壤中的碳有可能大量流失。因此，需要对植树造林生物多样性对整个生态系统碳平衡变化的影响进行实验测试。在此，我们介绍了森林与生物多样性实验（FAB1）启动 6 年后地上和地下碳库的变化，该实验包括在一个普通花园中种植 1、2、5 或 12 个树种的高密度地块。这些树木包括多种本地树种，既有针叶针叶树种，也有被子植物阔叶树种，既有外生菌根树种，也有丛生菌根树种。我们量化了物种丰富度、系统发育多样性和功能多样性对地上木质碳的影响，以及对矿质土壤碳积累、细根碳和土壤团聚的影响。令人惊讶的是，地上木质碳库的变化与矿质土壤碳库的变化并不相关，这表明土壤碳积累的变化并不是由植物枯落物输入量驱动的。地上木质部碳积累主要受物种和功能特性的影响；然而，物种丰富度和功能多样性较高的地块的地上木质部碳积累量比单一种植预期的要多。我们还发现，树种丰富度、特征和菌根类型对土壤碳积累的影响微弱但显著。为了评估微生物群落在这些影响中的作用，我们进一步比较了土壤碳库与磷脂脂肪酸（PLFA）图谱的变化。与微生物总生物量或植物多样性相比，土壤碳库和碳积累与特定微生物支系的相关性更强。我们的研究结果突出表明，在植树造林的最初几年，树木生物多样性对土壤碳储量的影响迅速显现，而且是通过微生物介导的，这种影响与地上木质生物量的增加无关。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Ecological Applications 环境科学-环境科学

CiteScore

9.50

自引率

2.00%

发文量

268

审稿时长

6 months

期刊介绍： The pages of Ecological Applications are open to research and discussion papers that integrate ecological science and concepts with their application and implications. Of special interest are papers that develop the basic scientific principles on which environmental decision-making should rest, and those that discuss the application of ecological concepts to environmental problem solving, policy, and management. Papers that deal explicitly with policy matters are welcome. Interdisciplinary approaches are encouraged, as are short communications on emerging environmental challenges.