abstract

• In this study, Chlorella sorokiniana FK, isolated from lead-zinc tailings, was employed for Pb(II) biomineralization with or without montmorillonite (MMT) addition in soil. Batch experiment results showed that montmorillonite facilitated Pb3(CO3)2(OH)2 formation on the surface of Chlorella-MMT composite, thus increasing algal cells’ tolerance to Pb(II) poisoning. Surprisingly, Pb(II) adsorbed and biomineralized by Chlorella-MMT composite was 2.69 times and 3.76 times as much as that by Chlorella alone, respectively. The montmorillonite facilitated Chlorella-induced Pb biomineralization by promoting both photosynthesis and urea hydrolysis, mainly due to more hydroxyl functional groups generated during its binding with Chlorella and its high pH buffering capacity. Moreover, the SEM-EDS analysis indicated that the biomineral particles shifted from algal cell surface to montmorillonite surface in the composite during long-term Pb-detoxification. In-situ soil Pb(II) remediation experiments with Chlorella-MMT composites further showed that Pb was immobilized as carbonate form in the short term and as residue fraction in the long term. This study made the first attempt to explore the facilitating effects of montmorillonite on metal-carbonate precipitation mediated by microalgae and to develop a green, sustainable, and effective strategy for immobilization of heavy metal in soil by combining clay minerals and microalgae. © 2021 Elsevier B.V.

authors

• Li Y.
• Song S.
• Xia L.
• Zhang Z.

publication date

• 2022-01-01

funding provided via

• National Natural Science Foundation of China (Grant Nos. 32061123009 , 52074203 ), Qingchuang Talent Incubation Program from Colleges and universities in Shandong Province (Grant No. 2019.133 )  Grant

published in

• Journal of Hazardous Materials  Journal

keywords

• Biomineralization; Microalgae; Montmorillonite; Pb(II); Soil remediation Biomineralization; Cell membranes; Clay minerals; Detoxification; Heavy metals; Lead compounds; Metabolism; Microorganisms; Precipitation (chemical); Remediation; Soil pollution; Soils; Urea; Algal cells; Batch experiments; Chlorella sorokiniana; High pH; Lead-zinc tailing; Montmorillonite composites; Pb(II); pH buffering capacity; Soils remediation; Urea hydrolysis; Microalgae; carbonic acid; functional group; hydroxyl group; lead; montmorillonite; urea; zinc; bentonite; lead; bicarbonate; biomineralization; green alga; heavy metal; hydrolysis; immobilization; microalga; montmorillonite; photosynthesis; adsorption; Article; batch process; biomass; biomineralization; bioremediation; biosorption; cell surface; Chlorella sorokiniana; controlled study; detoxification; energy dispersive X ray spectroscopy; Fourier transform infrared spectroscopy; hexagonal crystal; high resolution transmission electron microscopy; hydrolysis; immobilization; lead poisoning; microalga; mine tailings; nonhuman; pH; photosynthesis; precipitation; scanning electron microscopy; soil microflora; soil pollution; soil treatment; surface charge; surface property; X ray diffraction; X ray photoemission spectroscopy; zeta potential; biomineralization; Chlorella; soil; Chlorella sorokiniana; Bentonite; Biomineralization; Chlorella; Lead; Soil

Digital Object Identifier (DOI)

• 10.1016/j.jhazmat.2021.127007

PubMed ID

• 34523473

start page

end page

volume

• 423

issue