Efficiency of lime, biochar, Fe containing biochar and composite amendments for Cd and Pb immobilization in a co-contaminated alluvial soil

Efficiency of lime, biochar, Fe containing biochar and composite amendments for Cd and Pb immobilization in a co-contaminated alluvial soil

Present study reports the laboratory and field scale application of different organic and inorganic amendments to immobilize cadmium (Cd) and lead (Pb) in a co-contaminated alluvial paddy soil. For that purpose, lime, biochar, Fe-biochar and two composite amendments (CA) composed of biochar, lime, s...

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Bibliographic Details
Published in:Environmental pollution (1987) Vol. 257; p. 113609
Main Authors: Hamid, Yasir, Tang, Lin, Hussain, Bilal, Usman, Muhammad, Gurajala, Hanumanth Kumar, Rashid, Muhammad Saqib, He, Zhenli, Yang, Xiaoe
Format: Journal Article
Language:English
Published: England Elsevier Ltd 01-02-2020
Subjects:
Alluvial soil
Cadmium - chemistry
Calcium Compounds
Charcoal - chemistry
Composite amendments
Environmental Restoration and Remediation
FTIR
Lead - chemistry
Metals immobilization
Oryza
Oxides
SEM-EDS
Soil
Soil Pollutants
Speciation
Metals immobilization
Composite amendments
SEM-EDS
Alluvial soil
FTIR
Speciation
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Summary:Present study reports the laboratory and field scale application of different organic and inorganic amendments to immobilize cadmium (Cd) and lead (Pb) in a co-contaminated alluvial paddy soil. For that purpose, lime, biochar, Fe-biochar and two composite amendments (CA) composed of biochar, lime, sepiolite and zeolite (CA1: composite amendment 1) and manure, lime and sepiolite (CA2: composite amendment 2) were firstly tested in an incubation experiment to ameliorate Cd and Pb co-contaminated alluvial soil. It was observed that liming and CA2 elevated the soil pH and reduced DTPA extractable Cd and Pb in the incubated soil leading to higher metal immobilization. Therefore, efficiency of lime and CA2 was further investigated in field conditions with mid rice as the test crop to evaluate field scale immobilization and precise application rate for the tested soil type. DTPA and CaCl2 extractable Cd (46 and 51%) and Pb (68 and 70%) in field soil were decreased with applied treatments. Speciation of Cd and Pb also promoted conversion of metal exchangeable contents to less-available forms. Activated functional groups on amendments’ surface (_OH bonding, C_O and CO, -O-H, Si–O–Si, carboxylic and ester groups) sequestered metals by precipitation, adsorption, ion exchange or electro static attributes. Application of lime at 2400 kg/acre (T4) and CA2 at 1200 kg/acre was more effective in reducing rice shoot and grains metal contents. Moreover, obtained results in terms of pH, extractable content, speciation and yield, and microanalysis of amendments highlights the remarkable efficiency of lime and composite amendment to sorb Cd and Pb providing the key evidence of these amendments for metals immobilization and environmental remediation. Considering these results, lime and CA2 are potential amendments for co-contaminated rice field especially in context of alluvial soil. [Display omitted] •Inorganic, organic and composite amendments decreased the DTPA extractable metals.•Lime addition elevates incubated and field soil pH.•Cd and Pb speciation reduced exchangeable form of metals.•Lime and CA2 were effective in reducing metal availability in alluvial soil. Inorganic and organic additives have potential to remediate metal polluted sites but their composite application was more helpful in reducing Cd and Pb availability in co-contaminated alluvial soil.
ISSN:0269-7491
1873-6424
DOI:10.1016/j.envpol.2019.113609