Manure-residue co-application drives SOC sequestration through differential microbial strategist selection

Fan Huang; Hailun Wang; Sajjad Raza; Kazem Zamanian; Yinku Liang; Xiaoning Zhao

doi:10.1016/j.eti.2025.104109

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Originalsprache	Englisch
Aufsatznummer	104109
Fachzeitschrift	Environmental Technology and Innovation
Jahrgang	38
Frühes Online-Datum	25 Feb. 2025
Publikationsstatus	Elektronisch veröffentlicht (E-Pub) - 25 Feb. 2025

Abstract

This study investigated how fertilizer affects microbial communities and carbon storage in soils with contrasting organic carbon levels (16.3 % vs. 1 % SOC). Soils were incubated for 67 days (25°C, 60 % water-filled pores) under four treatments: (NH₄)₂SO₄, manure, (NH₄)₂SO₄ with garlic stalk (RGS), and manure with RGS. The results reveal that alone (NH₄)₂SO₄ increased Proteobacteria relative abundance by 129 % (significantly higher than alone manure's 51 %) in high SOC soil (16.3 %). Manure combined with RGS enhanced K-strategists (+33 %), reduced r/K ratio, stabilized carbon pools, and achieved the highest SOC increment (+21 mg g⁻¹). In low SOC soil (1 %), RGS amended treatments triggered explosive growth of Firmicutes (+382–615 %), amplified r-strategists (+13 %) with elevated r/K ratios (39−47), driving soil organic carbon accumulation (+25 mg g⁻¹). The findings demonstrate that coordinated manure application with residues optimizes soil carbon through divergent microbial strategies - reinforcing K-strategists for carbon stabilization in high-SOC soils while activating r-strategists for carbon formation in low-SOC soils, achieving soil carbon pool enhancement.

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Agrar- und Biowissenschaften (insg.)
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Manure-residue co-application drives SOC sequestration through differential microbial strategist selection. / Huang, Fan; Wang, Hailun; Raza, Sajjad et al.
in: Environmental Technology and Innovation, Jahrgang 38, 104109, 05.2025.

Publikation: Beitrag in Fachzeitschrift › Artikel › Forschung › Peer-Review

Huang, F, Wang, H, Raza, S, Zamanian, K, Liang, Y & Zhao, X 2025, 'Manure-residue co-application drives SOC sequestration through differential microbial strategist selection', Environmental Technology and Innovation, Jg. 38, 104109. https://doi.org/10.1016/j.eti.2025.104109

Huang, F., Wang, H., Raza, S., Zamanian, K., Liang, Y., & Zhao, X. (2025). Manure-residue co-application drives SOC sequestration through differential microbial strategist selection. Environmental Technology and Innovation, 38, Artikel 104109. Vorabveröffentlichung online. https://doi.org/10.1016/j.eti.2025.104109

Huang F, Wang H, Raza S, Zamanian K, Liang Y, Zhao X. Manure-residue co-application drives SOC sequestration through differential microbial strategist selection. Environmental Technology and Innovation. 2025 Mai;38:104109. Epub 2025 Feb 25. doi: 10.1016/j.eti.2025.104109

Huang, Fan ; Wang, Hailun ; Raza, Sajjad et al. / Manure-residue co-application drives SOC sequestration through differential microbial strategist selection. in: Environmental Technology and Innovation. 2025 ; Jahrgang 38.

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title = "Manure-residue co-application drives SOC sequestration through differential microbial strategist selection",

abstract = "This study investigated how fertilizer affects microbial communities and carbon storage in soils with contrasting organic carbon levels (16.3 % vs. 1 % SOC). Soils were incubated for 67 days (25°C, 60 % water-filled pores) under four treatments: (NH₄)₂SO₄, manure, (NH₄)₂SO₄ with garlic stalk (RGS), and manure with RGS. The results reveal that alone (NH₄)₂SO₄ increased Proteobacteria relative abundance by 129 % (significantly higher than alone manure's 51 %) in high SOC soil (16.3 %). Manure combined with RGS enhanced K-strategists (+33 %), reduced r/K ratio, stabilized carbon pools, and achieved the highest SOC increment (+21 mg g−1). In low SOC soil (1 %), RGS amended treatments triggered explosive growth of Firmicutes (+382–615 %), amplified r-strategists (+13 %) with elevated r/K ratios (39−47), driving soil organic carbon accumulation (+25 mg g−1). The findings demonstrate that coordinated manure application with residues optimizes soil carbon through divergent microbial strategies - reinforcing K-strategists for carbon stabilization in high-SOC soils while activating r-strategists for carbon formation in low-SOC soils, achieving soil carbon pool enhancement.",

keywords = "Fertilization, R- and K- strategists, Residue returning, SOC storage, Soil bacterial community, Soil bacterial diversity",

author = "Fan Huang and Hailun Wang and Sajjad Raza and Kazem Zamanian and Yinku Liang and Xiaoning Zhao",

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doi = "10.1016/j.eti.2025.104109",

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T1 - Manure-residue co-application drives SOC sequestration through differential microbial strategist selection

AU - Huang, Fan

AU - Wang, Hailun

AU - Raza, Sajjad

AU - Zamanian, Kazem

AU - Liang, Yinku

AU - Zhao, Xiaoning

PY - 2025/2/25

Y1 - 2025/2/25

N2 - This study investigated how fertilizer affects microbial communities and carbon storage in soils with contrasting organic carbon levels (16.3 % vs. 1 % SOC). Soils were incubated for 67 days (25°C, 60 % water-filled pores) under four treatments: (NH₄)₂SO₄, manure, (NH₄)₂SO₄ with garlic stalk (RGS), and manure with RGS. The results reveal that alone (NH₄)₂SO₄ increased Proteobacteria relative abundance by 129 % (significantly higher than alone manure's 51 %) in high SOC soil (16.3 %). Manure combined with RGS enhanced K-strategists (+33 %), reduced r/K ratio, stabilized carbon pools, and achieved the highest SOC increment (+21 mg g−1). In low SOC soil (1 %), RGS amended treatments triggered explosive growth of Firmicutes (+382–615 %), amplified r-strategists (+13 %) with elevated r/K ratios (39−47), driving soil organic carbon accumulation (+25 mg g−1). The findings demonstrate that coordinated manure application with residues optimizes soil carbon through divergent microbial strategies - reinforcing K-strategists for carbon stabilization in high-SOC soils while activating r-strategists for carbon formation in low-SOC soils, achieving soil carbon pool enhancement.

AB - This study investigated how fertilizer affects microbial communities and carbon storage in soils with contrasting organic carbon levels (16.3 % vs. 1 % SOC). Soils were incubated for 67 days (25°C, 60 % water-filled pores) under four treatments: (NH₄)₂SO₄, manure, (NH₄)₂SO₄ with garlic stalk (RGS), and manure with RGS. The results reveal that alone (NH₄)₂SO₄ increased Proteobacteria relative abundance by 129 % (significantly higher than alone manure's 51 %) in high SOC soil (16.3 %). Manure combined with RGS enhanced K-strategists (+33 %), reduced r/K ratio, stabilized carbon pools, and achieved the highest SOC increment (+21 mg g−1). In low SOC soil (1 %), RGS amended treatments triggered explosive growth of Firmicutes (+382–615 %), amplified r-strategists (+13 %) with elevated r/K ratios (39−47), driving soil organic carbon accumulation (+25 mg g−1). The findings demonstrate that coordinated manure application with residues optimizes soil carbon through divergent microbial strategies - reinforcing K-strategists for carbon stabilization in high-SOC soils while activating r-strategists for carbon formation in low-SOC soils, achieving soil carbon pool enhancement.

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KW - R- and K- strategists

KW - Residue returning

KW - SOC storage

KW - Soil bacterial community

KW - Soil bacterial diversity

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DO - 10.1016/j.eti.2025.104109

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JO - Environmental Technology and Innovation

JF - Environmental Technology and Innovation

SN - 2352-1864

M1 - 104109

ER -

Research@Leibniz University

Manure-residue co-application drives SOC sequestration through differential microbial strategist selection

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