AI Article Synopsis
- Biochar is a special type of charcoal that can help fight climate change in farming, but its effects when paired with high carbon dioxide levels (eCO) are not fully understood.
- A study used white lupin plants to see how eCO and biochar influenced plant nutrient uptake and soil bacteria, focusing on how plants absorb carbon, nitrogen, and phosphorus (C:N:P) nutrients.
- The results showed that while eCO made plants grow more, biochar actually reduced how much nitrogen and phosphorus they took in, and soil bacteria also changed in ways that affect how nutrients cycle in the soil.
Article Abstract
Biochar application is a potent climate change mitigation strategy in agroecosystems. However, little is known about the interactive effects of elevated CO (eCO) and biochar on plant nutrient uptake and soil microbial processes. A pot experiment was conducted to investigate the effects of eCO and biochar addition on plant C:N:P stoichiometry and rhizobacterial community for better management of nutrient balance and use efficiency in a future climate scenario. White lupin (Lupinus albus L.) was grown for 30 days in topsoil and subsoil with or without 2% corn-stubble biochar under ambient CO (aCO: 390 ppm) or eCO (550 ppm). Elevated CO increased, but biochar decreased, plant biomass and shoot N and P uptake, with no interactions in either soil layer. Elevated CO decreased shoot N concentration by 16% and biochar decreased shoot P concentration by 11%. As a result, eCO increased shoot C:N ratio by 20% and decreased the N:P ratio by 11%. Biochar decreased shoot C:N ratio by 8% in the subsoil under eCO. However, biochar increased shoot C:P ratio by an average of 13% and N:P ratio by 23% in the subsoil. Moreover, plants grown in the subsoil showed lower shoot N (35%) and P (70%) uptake compared to the topsoil. The results indicate that N and P are the more limiting factors that regulate plant growth under eCO and biochar application, respectively. Elevated CO and biochar oppositely affected dominant rhizobacterial community composition, with the eCO effect being greater. The microbiota in the subsoil held a greater diversity of contrasting species than the topsoil, which were associated with nutrient cycling, hydrocarbon degradation and plant productivity. These results enrich our understanding of potential soil nutrient cycling and plant nutrient balance in future agroecosystems.
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| http://dx.doi.org/10.1016/j.chemosphere.2022.136347 | DOI Listing |
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