Valuable non-food crops for biochar-assisted phytoremediation of contaminated soils: The case of cardoon, rapeseed and safflower

Biochar can affect the bioavailability of potentially toxic elements (PTEs) in contaminated soils thereby influencing plant growth. For this reason, biochar could be a resource for the assisted phytostabilisation of PTEs-polluted soils. The aim of this study was therefore to assess the influence of...

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Published in:Applied soil ecology : a section of Agriculture, ecosystems & environment ecosystems & environment, 2024-06, Vol.198, p.105349, Article 105349
Main Authors: Diquattro, Stefania, Pinna, Maria Vittoria, Garau, Matteo, Pulina, Antonio, Obinu, Lia, Porceddu, Andrea, Roggero, Pier Paolo, Castaldi, Paola, Garau, Giovanni
Format: Article
Language:English
Subjects:
Actinobacteria
bioavailability
biochar
biomass
cardoons
Carthamus tinctorius
Cyanobacteria
Gentle remediation options
income
Microbial abundance
Microbial diversity
nitrogen
phytoremediation
plant growth
Potentially toxic elements
PTEs-uptake
rapeseed
Salinisphaerales
soil
soil ecology
soil enzymes
toxicity
urease
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Summary:Biochar can affect the bioavailability of potentially toxic elements (PTEs) in contaminated soils thereby influencing plant growth. For this reason, biochar could be a resource for the assisted phytostabilisation of PTEs-polluted soils. The aim of this study was therefore to assess the influence of a softwood-derived biochar (5 % w/w), added to soils (S1 and S2) contaminated with Cd (4.8 and 74 mg·kg−1), Pb (318 and 1899 mg·kg−1) and Zn (622 and 3803 mg·kg−1), on selected soil biochemical and microbial features. The suitability of biochar in the assisted phytostabilisation in combination with cardoon, rapeseed and safflower was also evaluated. Overall, biochar decreased (or left unaffected) the number of culturable bacteria, actinomycetes and fungi in both soils. Soil enzyme activities were also reduced by biochar (e.g., −64 and 75 % for dehydrogenase and −16 % and 22 % for β-glucosidase in S1- and S2 + Bio), while urease activity increased (+190 and 46 % in S1- and S2 + Bio). Actinobacteria and bacterial taxa involved in soil nitrogen cycling (e.g., Nitrospira) were enriched in biochar-amended soils, while a marked loss of Cyanobacteria and taxa associated with oligotrophic conditions (e.g. Gaiellales, Sericithochromatia, Methylinbuim, Solimonadaceae, Gammaprotobacteriaceae and Salinisphaerales) was recorded. Increased root biomass of cardoon (+22 and 14 % in S1- and S2 + Bio compared to control plants), safflower (+71 and 98 % in S1- and S2 + Bio), and rapeseed (+17.1 + 2.4 % in S1- and S2 + Bio) was recorded in the amended soils. An increase of safflower and rapeseed shoots was also detected. In most cases, biochar addition reduced the PTEs concentration in plant roots/shoots/seeds favouring their build up (as total amounts) in the roots, as a consequence of enhanced growth due to biochar. Overall, the results indicated that safflower, rapeseed and cardoon can be used in assisted phytoremediation programmes of PTEs-contaminated soils, providing some valuable biomass that can generate income. [Display omitted] •Biochar changed the microbial community of soils contaminated with Cd, Pb and Zn.•Biochar induced an enrichment of bacterial genera related to nitrogen metabolism.•The root biomass of cardoon, safflower and rapeseed increased in the amended soils.•A rise of safflower and rapeseed shoots was also detected in biochar-treated soils.•Biochar addition reduced the PTEs uptake and favoured their retention in the roots.
ISSN:0929-1393
1873-0272
DOI:10.1016/j.apsoil.2024.105349