Soil organic carbon, total nitrogen, available nutrients, and yield under different straw returning methods

•Straw mulching (SM) and straw burying (SB) increase crop yields and soil nutrient contents.•SB is more conducive to increasing soil organic carbon, soil total nitrogen, and soil total potassium than SM.•SM is more conducive to increase soil available nitrogen, soil available phosphorus, and soil av...

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Published inSoil & tillage research Vol. 214; p. 105171
Main Authors Huang, Tiantian, Yang, Ning, Lu, Chen, Qin, Xiaoliang, Siddique, Kadambot H.M.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.10.2021
Subjects
atmospheric precipitation
bioactive properties
China
Crop yield
meta-analysis
nitrogen
nutrient availability
phosphorus
potassium
soil
Soil available nutrients
soil fertility
soil nutrients
Soil organic carbon
Soil total nitrogen
straw
Straw burying
Straw mulching
tillage
total nitrogen
total phosphorus
China
Soil available nutrients
Soil total nitrogen
Straw burying
Soil organic carbon
Straw mulching
Crop yield
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Abstract •Straw mulching (SM) and straw burying (SB) increase crop yields and soil nutrient contents.•SB is more conducive to increasing soil organic carbon, soil total nitrogen, and soil total potassium than SM.•SM is more conducive to increase soil available nitrogen, soil available phosphorus, and soil available potassium than SB.•SM performed better than SB in arid regions.•SB performed better than SM where mean annual precipitation is >800 mm. Straw returning is an important measure for improving soil organic matter, biological activity, and nutrient availability. Straw mulching and straw burying are two methods for returning straw to the soil; however, there is little information to compare their benefits and limitations. This study assessed changes in soil nutrients induced by straw mulching and straw burying using a meta-analysis of straw returning data from 420 publications in China. The results showed that straw burying significantly increased soil organic carbon (SOC), soil total nitrogen (STN), soil total phosphorus (STP), soil total potassium (STK), soil available nitrogen (SAN), soil available phosphorus (SAP), and soil available potassium (SAK) in the surface soil (0–20 cm), with mean effect sizes of 0.126, 0.095, 0.056, 0.053, 0.118, 0.117, 0.138, respectively. Straw mulching increased SOC, STN, STP, SAN, SAP, and SAK in the surface soil, with mean effect sizes of 0.114, 0.079, 0.082, 0.125, 0.152, 0.150, respectively. Straw burying is more conducive to increasing SOC, STN, and STK, while straw mulching is more conducive to increasing SAN, SAP, and SAK. Straw mulching increased soil nutrient contents more than straw burying in areas with mean annual precipitation (MAP) <400 mm, while the reverse was true in areas with MAP> 800 mm. Straw mulching and straw burying both increased crop yield, with mean effect sizes of 0.100 and 0.101, respectively. Straw burying positively correlated with the effect size of yield, SOC, SAP, and SAK, while there were no significant relationships for straw mulching. Long-term straw burying and straw mulching was conducive to increasing crop yields, SOC, and STN. The benefits and limitations of straw mulching and burying on soil fertility and yield vary under different agronomic management, environmental, and edaphic factors.
AbstractList Straw returning is an important measure for improving soil organic matter, biological activity, and nutrient availability. Straw mulching and straw burying are two methods for returning straw to the soil; however, there is little information to compare their benefits and limitations. This study assessed changes in soil nutrients induced by straw mulching and straw burying using a meta-analysis of straw returning data from 420 publications in China. The results showed that straw burying significantly increased soil organic carbon (SOC), soil total nitrogen (STN), soil total phosphorus (STP), soil total potassium (STK), soil available nitrogen (SAN), soil available phosphorus (SAP), and soil available potassium (SAK) in the surface soil (0–20 cm), with mean effect sizes of 0.126, 0.095, 0.056, 0.053, 0.118, 0.117, 0.138, respectively. Straw mulching increased SOC, STN, STP, SAN, SAP, and SAK in the surface soil, with mean effect sizes of 0.114, 0.079, 0.082, 0.125, 0.152, 0.150, respectively. Straw burying is more conducive to increasing SOC, STN, and STK, while straw mulching is more conducive to increasing SAN, SAP, and SAK. Straw mulching increased soil nutrient contents more than straw burying in areas with mean annual precipitation (MAP) <400 mm, while the reverse was true in areas with MAP> 800 mm. Straw mulching and straw burying both increased crop yield, with mean effect sizes of 0.100 and 0.101, respectively. Straw burying positively correlated with the effect size of yield, SOC, SAP, and SAK, while there were no significant relationships for straw mulching. Long-term straw burying and straw mulching was conducive to increasing crop yields, SOC, and STN. The benefits and limitations of straw mulching and burying on soil fertility and yield vary under different agronomic management, environmental, and edaphic factors.
•Straw mulching (SM) and straw burying (SB) increase crop yields and soil nutrient contents.•SB is more conducive to increasing soil organic carbon, soil total nitrogen, and soil total potassium than SM.•SM is more conducive to increase soil available nitrogen, soil available phosphorus, and soil available potassium than SB.•SM performed better than SB in arid regions.•SB performed better than SM where mean annual precipitation is >800 mm. Straw returning is an important measure for improving soil organic matter, biological activity, and nutrient availability. Straw mulching and straw burying are two methods for returning straw to the soil; however, there is little information to compare their benefits and limitations. This study assessed changes in soil nutrients induced by straw mulching and straw burying using a meta-analysis of straw returning data from 420 publications in China. The results showed that straw burying significantly increased soil organic carbon (SOC), soil total nitrogen (STN), soil total phosphorus (STP), soil total potassium (STK), soil available nitrogen (SAN), soil available phosphorus (SAP), and soil available potassium (SAK) in the surface soil (0–20 cm), with mean effect sizes of 0.126, 0.095, 0.056, 0.053, 0.118, 0.117, 0.138, respectively. Straw mulching increased SOC, STN, STP, SAN, SAP, and SAK in the surface soil, with mean effect sizes of 0.114, 0.079, 0.082, 0.125, 0.152, 0.150, respectively. Straw burying is more conducive to increasing SOC, STN, and STK, while straw mulching is more conducive to increasing SAN, SAP, and SAK. Straw mulching increased soil nutrient contents more than straw burying in areas with mean annual precipitation (MAP) <400 mm, while the reverse was true in areas with MAP> 800 mm. Straw mulching and straw burying both increased crop yield, with mean effect sizes of 0.100 and 0.101, respectively. Straw burying positively correlated with the effect size of yield, SOC, SAP, and SAK, while there were no significant relationships for straw mulching. Long-term straw burying and straw mulching was conducive to increasing crop yields, SOC, and STN. The benefits and limitations of straw mulching and burying on soil fertility and yield vary under different agronomic management, environmental, and edaphic factors.
ArticleNumber 105171
Author Siddique, Kadambot H.M.
Lu, Chen
Qin, Xiaoliang
Huang, Tiantian
Yang, Ning
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  surname: Huang
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  givenname: Ning
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  organization: College of Agronomy/State Key Laboratory of Soil Erosion and Dryland Farming on the Loess Plateau, Northwest A&F University, Yangling, Shaanxi 712100, China
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  givenname: Chen
  surname: Lu
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  organization: College of Agronomy/State Key Laboratory of Soil Erosion and Dryland Farming on the Loess Plateau, Northwest A&F University, Yangling, Shaanxi 712100, China
– sequence: 4
  givenname: Xiaoliang
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  givenname: Kadambot H.M.
  orcidid: 0000-0001-6097-4235
  surname: Siddique
  fullname: Siddique, Kadambot H.M.
  organization: The UWA Institute of Agriculture and School of Agriculture & Environment, The University of Western Australia, Perth, WA 6001, Australia
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Keywords Soil available nutrients
Soil total nitrogen
Straw burying
Soil organic carbon
Straw mulching
Crop yield
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Snippet •Straw mulching (SM) and straw burying (SB) increase crop yields and soil nutrient contents.•SB is more conducive to increasing soil organic carbon, soil total...
Straw returning is an important measure for improving soil organic matter, biological activity, and nutrient availability. Straw mulching and straw burying are...
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SubjectTerms atmospheric precipitation
bioactive properties
China
Crop yield
meta-analysis
nitrogen
nutrient availability
phosphorus
potassium
soil
Soil available nutrients
soil fertility
soil nutrients
Soil organic carbon
Soil total nitrogen
straw
Straw burying
Straw mulching
tillage
total nitrogen
total phosphorus
Title Soil organic carbon, total nitrogen, available nutrients, and yield under different straw returning methods
URI https://dx.doi.org/10.1016/j.still.2021.105171
https://www.proquest.com/docview/2636545893
Volume 214
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