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Resolving the Intricate Effects of Multiple Global Change Drivers on Root Litter Decomposition

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Resolving the Intricate Effects of Multiple Global Change Drivers on Root Litter Decomposition. / Zhao, Qingzhou; Freschet, Grégoire T; Tao, Tingting et al.
In: Global Change Biology, Vol. 30, No. 10, e17547, 31.10.2024.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Zhao, Q, Freschet, GT, Tao, T, Smith, GR, Wang, P, Hu, L, Ma, M, Johnson, D, Crowther, TW & Hu, S 2024, 'Resolving the Intricate Effects of Multiple Global Change Drivers on Root Litter Decomposition', Global Change Biology, vol. 30, no. 10, e17547. https://doi.org/10.1111/gcb.17547

APA

Zhao, Q., Freschet, GT., Tao, T., Smith, GR., Wang, P., Hu, L., Ma, M., Johnson, D., Crowther, TW., & Hu, S. (2024). Resolving the Intricate Effects of Multiple Global Change Drivers on Root Litter Decomposition. Global Change Biology, 30(10), Article e17547. https://doi.org/10.1111/gcb.17547

Vancouver

Zhao Q, Freschet GT, Tao T, Smith GR, Wang P, Hu L et al. Resolving the Intricate Effects of Multiple Global Change Drivers on Root Litter Decomposition. Global Change Biology. 2024 Oct 31;30(10):e17547. Epub 2024 Oct 28. doi: 10.1111/gcb.17547

Author

Zhao, Qingzhou ; Freschet, Grégoire T ; Tao, Tingting et al. / Resolving the Intricate Effects of Multiple Global Change Drivers on Root Litter Decomposition. In: Global Change Biology. 2024 ; Vol. 30, No. 10.

Bibtex

@article{9498be8001be4c2286f681040f9757c9,
title = "Resolving the Intricate Effects of Multiple Global Change Drivers on Root Litter Decomposition",
abstract = "Plant roots represent about a quarter of global plant biomass and constitute a primary source of soil organic carbon (C). Yet, considerable uncertainty persists regarding root litter decomposition and their responses to global change factors (GCFs). Much of this uncertainty stems from a limited understanding of the multifactorial effects of GCFs and it remains unclear how these effects are mediated by litter quality, soil conditions and microbial functionality. Using complementary field decomposition and laboratory incubation approaches, we assessed the relative controls of GCF-mediated changes in root litter traits and soil and microbial properties on fine-root decomposition under warming, nitrogen (N) enrichment, and precipitation alteration. We found that warming and N enrichment accelerated fine-root decomposition by over 10%, and their combination showed an additive effect, while precipitation reduction suppressed decomposition overall by 12%, with the suppressive effect being most significant under warming-alone and N enrichment-alone conditions. Significantly, changes in litter quality played a dominant role and accelerated fine-root decomposition by 15% ~ 18% under warming and N enrichment, while changes in soil and microbial properties were predominant and reduced decomposition by 7% ~ 10% under precipitation reduction and the combined warming and N enrichment. Examining only the decomposition environment or litter properties in isolation can distort global change effects on root decomposition, underestimating precipitation reduction impacts by 38% and overstating warming and N effects by up to 73%. These findings highlight that the net impact of GCFs on root litter decomposition hinges on the interplay between GCF-modulated root decomposability and decomposition environment, as well as on the synergistic or antagonistic relationships among GCFs themselves. Our study emphasizes that integrating the legacy effects of multiple GCFs on root traits, soil conditions and microbial functionality would improve our prediction of C and nutrient cycling under interactive global change scenarios.",
keywords = "global change factors, microbial respiration, nutrient cycling, plant functional traits, root decomposition, root traits",
author = "Qingzhou Zhao and Gr{\'e}goire T Freschet and Tingting Tao and Gabriel Reuben Smith and Peng Wang and Lingyan Hu and Miaojun Ma and David Johnson and Thomas W Crowther and Shuijin Hu",
note = "Publisher Copyright: {\textcopyright} 2024 John Wiley & Sons Ltd. M1 - e17547",
year = "2024",
month = oct,
day = "31",
doi = "10.1111/gcb.17547",
language = "English",
volume = "30",
journal = "Global Change Biology",
issn = "1354-1013",
publisher = "Blackwell Publishing Ltd",
number = "10",

}

RIS

TY - JOUR

T1 - Resolving the Intricate Effects of Multiple Global Change Drivers on Root Litter Decomposition

AU - Zhao, Qingzhou

AU - Freschet, Grégoire T

AU - Tao, Tingting

AU - Smith, Gabriel Reuben

AU - Wang, Peng

AU - Hu, Lingyan

AU - Ma, Miaojun

AU - Johnson, David

AU - Crowther, Thomas W

AU - Hu, Shuijin

N1 - Publisher Copyright: © 2024 John Wiley & Sons Ltd. M1 - e17547

PY - 2024/10/31

Y1 - 2024/10/31

N2 - Plant roots represent about a quarter of global plant biomass and constitute a primary source of soil organic carbon (C). Yet, considerable uncertainty persists regarding root litter decomposition and their responses to global change factors (GCFs). Much of this uncertainty stems from a limited understanding of the multifactorial effects of GCFs and it remains unclear how these effects are mediated by litter quality, soil conditions and microbial functionality. Using complementary field decomposition and laboratory incubation approaches, we assessed the relative controls of GCF-mediated changes in root litter traits and soil and microbial properties on fine-root decomposition under warming, nitrogen (N) enrichment, and precipitation alteration. We found that warming and N enrichment accelerated fine-root decomposition by over 10%, and their combination showed an additive effect, while precipitation reduction suppressed decomposition overall by 12%, with the suppressive effect being most significant under warming-alone and N enrichment-alone conditions. Significantly, changes in litter quality played a dominant role and accelerated fine-root decomposition by 15% ~ 18% under warming and N enrichment, while changes in soil and microbial properties were predominant and reduced decomposition by 7% ~ 10% under precipitation reduction and the combined warming and N enrichment. Examining only the decomposition environment or litter properties in isolation can distort global change effects on root decomposition, underestimating precipitation reduction impacts by 38% and overstating warming and N effects by up to 73%. These findings highlight that the net impact of GCFs on root litter decomposition hinges on the interplay between GCF-modulated root decomposability and decomposition environment, as well as on the synergistic or antagonistic relationships among GCFs themselves. Our study emphasizes that integrating the legacy effects of multiple GCFs on root traits, soil conditions and microbial functionality would improve our prediction of C and nutrient cycling under interactive global change scenarios.

AB - Plant roots represent about a quarter of global plant biomass and constitute a primary source of soil organic carbon (C). Yet, considerable uncertainty persists regarding root litter decomposition and their responses to global change factors (GCFs). Much of this uncertainty stems from a limited understanding of the multifactorial effects of GCFs and it remains unclear how these effects are mediated by litter quality, soil conditions and microbial functionality. Using complementary field decomposition and laboratory incubation approaches, we assessed the relative controls of GCF-mediated changes in root litter traits and soil and microbial properties on fine-root decomposition under warming, nitrogen (N) enrichment, and precipitation alteration. We found that warming and N enrichment accelerated fine-root decomposition by over 10%, and their combination showed an additive effect, while precipitation reduction suppressed decomposition overall by 12%, with the suppressive effect being most significant under warming-alone and N enrichment-alone conditions. Significantly, changes in litter quality played a dominant role and accelerated fine-root decomposition by 15% ~ 18% under warming and N enrichment, while changes in soil and microbial properties were predominant and reduced decomposition by 7% ~ 10% under precipitation reduction and the combined warming and N enrichment. Examining only the decomposition environment or litter properties in isolation can distort global change effects on root decomposition, underestimating precipitation reduction impacts by 38% and overstating warming and N effects by up to 73%. These findings highlight that the net impact of GCFs on root litter decomposition hinges on the interplay between GCF-modulated root decomposability and decomposition environment, as well as on the synergistic or antagonistic relationships among GCFs themselves. Our study emphasizes that integrating the legacy effects of multiple GCFs on root traits, soil conditions and microbial functionality would improve our prediction of C and nutrient cycling under interactive global change scenarios.

KW - global change factors

KW - microbial respiration

KW - nutrient cycling

KW - plant functional traits

KW - root decomposition

KW - root traits

U2 - 10.1111/gcb.17547

DO - 10.1111/gcb.17547

M3 - Journal article

VL - 30

JO - Global Change Biology

JF - Global Change Biology

SN - 1354-1013

IS - 10

M1 - e17547

ER -