Straw incorporation improved the adsorption of potassium by increasing the soil humic acid in macroaggregates

Straw incorporation improved the adsorption of potassium by increasing the soil humic acid in macroaggregates

Straw incorporation has been broadly demonstrated to be effective for the maintenance of soil potassium (K) fertility in farmlands, which increases K and carbon (C) inputs and improves soil stability due to aggregate formation and physiochemical bonding. However, the response of K retention in aggre...

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Veröffentlicht in:Journal of environmental management 2022-05, Vol.310, p.114665-114665, Article 114665
Hauptverfasser: Zhu, Dandan, Cong, Rihuan, Ren, Tao, Lu, Zhifeng, Lu, Jianwei, Li, Xiaokun
Format: Artikel
Sprache:eng
Schlagworte:
Adsorption
Aggregate fractions (AFs)
Agriculture - methods
C composition
Carbon - analysis
chemical structure
China
environmental management
equations
humic acids
Humic Substances
physicochemical properties
Potassium
soil
Soil - chemistry
soil aggregation
Soil K pools
soil organic carbon
Soil organic carbon (SOC)
straw
Straw incorporation
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container_end_page 114665
container_issue
container_start_page 114665
container_title Journal of environmental management
container_volume 310
creator Zhu, Dandan
Cong, Rihuan
Ren, Tao
Lu, Zhifeng
Lu, Jianwei
Li, Xiaokun
description Straw incorporation has been broadly demonstrated to be effective for the maintenance of soil potassium (K) fertility in farmlands, which increases K and carbon (C) inputs and improves soil stability due to aggregate formation and physiochemical bonding. However, the response of K retention in aggregate fractions (AFs) to soil organic carbon (SOC) changes is poorly understood. Field trials under a completely random experimental design considering two factors, straw return and K fertilization, were conducted to study the comprehensive effects of SOC and various AFs on soil K adsorption. The results indicated that the soil exchangeable and nonexchangeable K pools (EKP and NKP) increased upon straw incorporation due to an increase in macroaggregates (>2 mm fraction). The synergistic increase in SOC and humic acid (HA) contents, which resulted in a complex molecular structure and improved soil aggregation, promoted K adsorption. Good linear relationships existed between the apparent K balance and the EKP and NKP values in the >2 mm fraction. Structural equation modeling (SEM) indicated that SOC and various AFs exerted positive and significant effects on soil EKP and NKP, and thus verified 96% of the total variation in K adsorption. Thus, combination of straw and K fertilization increased the aggregate-associated C and K, which were primarily correlated with the >2 mm fraction. These direct measurements and estimates provide insights into the aggregates associated with K, which enhances the understanding of the chemical behavior of soil K upon straw incorporation. •The >2 mm aggregate-associated K was mostly correlated with soil K pools.•The increase in SOC resulted in a complex molecular structure and improved soil aggregation.•Straw incorporation improved soil HA and thus promoted K adsorption.
doi_str_mv 10.1016/j.jenvman.2022.114665
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However, the response of K retention in aggregate fractions (AFs) to soil organic carbon (SOC) changes is poorly understood. Field trials under a completely random experimental design considering two factors, straw return and K fertilization, were conducted to study the comprehensive effects of SOC and various AFs on soil K adsorption. The results indicated that the soil exchangeable and nonexchangeable K pools (EKP and NKP) increased upon straw incorporation due to an increase in macroaggregates (&gt;2 mm fraction). The synergistic increase in SOC and humic acid (HA) contents, which resulted in a complex molecular structure and improved soil aggregation, promoted K adsorption. Good linear relationships existed between the apparent K balance and the EKP and NKP values in the &gt;2 mm fraction. Structural equation modeling (SEM) indicated that SOC and various AFs exerted positive and significant effects on soil EKP and NKP, and thus verified 96% of the total variation in K adsorption. Thus, combination of straw and K fertilization increased the aggregate-associated C and K, which were primarily correlated with the &gt;2 mm fraction. 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Thus, combination of straw and K fertilization increased the aggregate-associated C and K, which were primarily correlated with the &gt;2 mm fraction. These direct measurements and estimates provide insights into the aggregates associated with K, which enhances the understanding of the chemical behavior of soil K upon straw incorporation. •The &gt;2 mm aggregate-associated K was mostly correlated with soil K pools.•The increase in SOC resulted in a complex molecular structure and improved soil aggregation.•Straw incorporation improved soil HA and thus promoted K adsorption.</abstract><cop>England</cop><pub>Elsevier Ltd</pub><pmid>35202948</pmid><doi>10.1016/j.jenvman.2022.114665</doi><tpages>1</tpages><orcidid>https://orcid.org/0000-0003-0279-082X</orcidid></addata></record>
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source MEDLINE; Elsevier ScienceDirect Journals
subjects Adsorption
Aggregate fractions (AFs)
Agriculture - methods
C composition
Carbon - analysis
chemical structure
China
environmental management
equations
humic acids
Humic Substances
physicochemical properties
Potassium
soil
Soil - chemistry
soil aggregation
Soil K pools
soil organic carbon
Soil organic carbon (SOC)
straw
Straw incorporation
title Straw incorporation improved the adsorption of potassium by increasing the soil humic acid in macroaggregates
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