Biochar addition reduces salinity in salt-affected soils with no impact on soil pH: A meta-analysis

•Biochar can alleviate soil salinity stress.•Biochar amendment does not modify the soil pH in salt-affected soils.•Biochar increases cation exchange capacity by 17.0% in salt-affected soils.•The impact of biochar addition on ECe depends on biochar feedstock and soil initial salinization level. Salin...

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Published in	Geoderma Vol. 443; p. 116845
Main Authors	Wang, Xiao, Ding, Jianli, Han, Lijing, Tan, Jiao, Ge, Xiangyu, Nan, Qiong
Format	Journal Article
Language	English
Published	Elsevier B.V 01.03.2024 Elsevier
Subjects	Amendment Biochar cation exchange capacity feedstocks Meta-analysis salinity Salinity level salt tolerance Salt-affected soils soil degradation soil electrical conductivity soil pH Amendment Salinity level Salt-affected soils Biochar Meta-analysis
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Abstract	•Biochar can alleviate soil salinity stress.•Biochar amendment does not modify the soil pH in salt-affected soils.•Biochar increases cation exchange capacity by 17.0% in salt-affected soils.•The impact of biochar addition on ECe depends on biochar feedstock and soil initial salinization level. Salinization remains a major issue in soil degradation, for which biochar is a potential solution. In this meta-analysis, using 660 paired observations from 99 peer-reviewed articles, we evaluated biochar's effect on salt-affected soils and identified the initial soil properties, biochar properties and experimental factors influencing its efficacy. The results showed that the addition of biochar had a significant ameliorating effect on salt-affected soils. The soil electrical conductivity of saturated paste extract (ECe) was significantly reduced by 13.2%, and such effect was significant in severe salinization soil (rather than slight and moderate salinization). Meanwhile, the soil cation exchange capacity was significantly increased by 17.0%. However, the addition of biochar had no significant impact on soil pH. Model selection analyses further indicated that the level of initial salinity and the type of biochar feedstock were the most important factors regulating the response of soil ECe to biochar addition. In summary, while our study highlights the potential of biochar in ameliorating salt-affected soils, particularly in severely salinized soils, it also underscores the need for more comprehensive research in this field. Additional research is necessary to comprehensively address the significant heterogeneity of biochars, including their thorough characterization. In addition, more studies are required to explore the impact of biochar on both salt-tolerant and non-salt-tolerant plants in salt-affected soils.
AbstractList	Salinization remains a major issue in soil degradation, for which biochar is a potential solution. In this meta-analysis, using 660 paired observations from 99 peer-reviewed articles, we evaluated biochar's effect on salt-affected soils and identified the initial soil properties, biochar properties and experimental factors influencing its efficacy. The results showed that the addition of biochar had a significant ameliorating effect on salt-affected soils. The soil electrical conductivity of saturated paste extract (ECe) was significantly reduced by 13.2%, and such effect was significant in severe salinization soil (rather than slight and moderate salinization). Meanwhile, the soil cation exchange capacity was significantly increased by 17.0%. However, the addition of biochar had no significant impact on soil pH. Model selection analyses further indicated that the level of initial salinity and the type of biochar feedstock were the most important factors regulating the response of soil ECe to biochar addition. In summary, while our study highlights the potential of biochar in ameliorating salt-affected soils, particularly in severely salinized soils, it also underscores the need for more comprehensive research in this field. Additional research is necessary to comprehensively address the significant heterogeneity of biochars, including their thorough characterization. In addition, more studies are required to explore the impact of biochar on both salt-tolerant and non-salt-tolerant plants in salt-affected soils. •Biochar can alleviate soil salinity stress.•Biochar amendment does not modify the soil pH in salt-affected soils.•Biochar increases cation exchange capacity by 17.0% in salt-affected soils.•The impact of biochar addition on ECe depends on biochar feedstock and soil initial salinization level. Salinization remains a major issue in soil degradation, for which biochar is a potential solution. In this meta-analysis, using 660 paired observations from 99 peer-reviewed articles, we evaluated biochar's effect on salt-affected soils and identified the initial soil properties, biochar properties and experimental factors influencing its efficacy. The results showed that the addition of biochar had a significant ameliorating effect on salt-affected soils. The soil electrical conductivity of saturated paste extract (ECe) was significantly reduced by 13.2%, and such effect was significant in severe salinization soil (rather than slight and moderate salinization). Meanwhile, the soil cation exchange capacity was significantly increased by 17.0%. However, the addition of biochar had no significant impact on soil pH. Model selection analyses further indicated that the level of initial salinity and the type of biochar feedstock were the most important factors regulating the response of soil ECe to biochar addition. In summary, while our study highlights the potential of biochar in ameliorating salt-affected soils, particularly in severely salinized soils, it also underscores the need for more comprehensive research in this field. Additional research is necessary to comprehensively address the significant heterogeneity of biochars, including their thorough characterization. In addition, more studies are required to explore the impact of biochar on both salt-tolerant and non-salt-tolerant plants in salt-affected soils.
ArticleNumber	116845
Author	Ding, Jianli Ge, Xiangyu Nan, Qiong Han, Lijing Tan, Jiao Wang, Xiao
Author_xml	– sequence: 1 givenname: Xiao surname: Wang fullname: Wang, Xiao organization: College of Geography and Remote Sensing Sciences, Xinjiang University, Urumqi 830017, China – sequence: 2 givenname: Jianli surname: Ding fullname: Ding, Jianli email: dingjl@xju.edu.cn organization: College of Geography and Remote Sensing Sciences, Xinjiang University, Urumqi 830017, China – sequence: 3 givenname: Lijing surname: Han fullname: Han, Lijing organization: College of Geography and Remote Sensing Sciences, Xinjiang University, Urumqi 830017, China – sequence: 4 givenname: Jiao surname: Tan fullname: Tan, Jiao organization: College of Geography and Remote Sensing Sciences, Xinjiang University, Urumqi 830017, China – sequence: 5 givenname: Xiangyu surname: Ge fullname: Ge, Xiangyu organization: College of Geography and Remote Sensing Sciences, Xinjiang University, Urumqi 830017, China – sequence: 6 givenname: Qiong surname: Nan fullname: Nan, Qiong organization: Institute of Environment Pollution Control and Treatment, College of Environment and Resource Science, Zhejiang University, Hangzhou 310029, China
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Snippet	•Biochar can alleviate soil salinity stress.•Biochar amendment does not modify the soil pH in salt-affected soils.•Biochar increases cation exchange capacity... Salinization remains a major issue in soil degradation, for which biochar is a potential solution. In this meta-analysis, using 660 paired observations from 99...
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SubjectTerms	Amendment Biochar cation exchange capacity feedstocks Meta-analysis salinity Salinity level salt tolerance Salt-affected soils soil degradation soil electrical conductivity soil pH
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Title	Biochar addition reduces salinity in salt-affected soils with no impact on soil pH: A meta-analysis
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