Factors regulating interaction among inorganic nitrogen and phosphorus species, plant uptake, and relevant cycling genes in a weakly alkaline soil treated with biochar and inorganic fertilizer

Factors regulating interaction among inorganic nitrogen and phosphorus species, plant uptake, and relevant cycling genes in a weakly alkaline soil treated with biochar and inorganic fertilizer

To highlight how biochar affects the interaction between inorganic nitrogen species (ammonium nitrogen, nitrate nitrogen, and nitrite nitrogen: NH4+-N, NO3¯-N, and NO2¯-N) and phosphorus species (calcium phosphate, iron phosphate, and aluminum phosphate: CaP, FeP and AlP) in soil and plant uptake of...

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Bibliographic Details
Published in:The Science of the total environment Vol. 905; p. 167280
Main Authors: Li, Hongyan, Ren, Rui, Zhang, Hongyu, Zhang, Guixiang, He, Qiusheng, Han, Zhiwang, Meng, Shuhui, Zhang, Yanli, Zhang, Xiaohui
Format: Journal Article
Language:English
Published: Elsevier B.V 20-12-2023
Subjects:
Bacterial community
Biochar
Genes
Inorganic nitrogen
Inorganic phosphorus
Soil
Soil
Inorganic nitrogen
Biochar
Inorganic phosphorus
Genes
Bacterial community
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Summary:To highlight how biochar affects the interaction between inorganic nitrogen species (ammonium nitrogen, nitrate nitrogen, and nitrite nitrogen: NH4+-N, NO3¯-N, and NO2¯-N) and phosphorus species (calcium phosphate, iron phosphate, and aluminum phosphate: CaP, FeP and AlP) in soil and plant uptake of these nutrients, walnut shell (WS)- and corn cob (CC)-derived biochars (0.5 %, 1 %, 2 %, and 4 %, w/w) were added to a weakly alkaline soil, and then Chinese cabbages were planted. The results showed that the changes in soil inorganic nitrogen were related to biochar feedstock, pyrolysis temperature, and application rate. For soil under the active nitrification condition (dominant NO3¯-N), a significant decrease in the NH4+-N/NO3¯-N ratio after biochar addition indicates enhanced nitrification (excluding WS-derived biochars at 2 % and 4 %), which can be explained by the most positive response of ammonia-oxidizing archaeal amoA to biochar addition. The CC-derived biochar more effectively enhanced soil nitrification than WS-derived biochar did. The addition of 4 % of biochars significantly increased soil inorganic phosphorus, and the addition of CC-derived biochars more effectively increased Ca2P than WS-derived biochars. Biochars significantly decreased plant uptake of phosphorus, while generally had little influence on plant uptake of nitrogen. Interestingly, NO2¯-N in soil significantly positively correlated with total phosphorus in both soil and plant, and significantly negatively correlated with phoC, indicating that a certain degree of NO2¯-N accumulation in soil slightly facilitated plant uptake of phosphorus but inhibited phoC-harboring bacteria. The NO3¯-N in soil significantly positively correlated with Ca2P and Ca8P, while the NH4+-N/NO3¯-N ratio significantly negatively correlated with Ca10P and FeP, indicating that the enhanced nitrification seemed to facilitate the change in phosphorus to readly available ones. This study will help determine how to scientifically and rationally use biochar to regulate inorganic nitrogen and phosphorus species in soil and plant uptake of these nutrients. [Display omitted] •Biochars enhanced nitrification in soil that was in the active nitrification condition.•Ammonia-oxidizing archaeal amoA had the most positively response to biochar addition.•A certain amount of NO2¯-N in soil might be favorable for plant uptake of phosphorus.•Enhanced nitrification facilitated for changing phosphorus to easily available ones.•Biochars decreased plant uptake of phosphorus from the soil with inorganic fertilizer.
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content type line 23
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2023.167280