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Phytomanagement with forage grasses for sustainable remediation of contaminated tailings soil: Enhancing soil functionality and addressing forage safety risks

Jun Chen, Weixia Hao, Yichen Shi, Liping Chen, Haiyan Li, Zhiwei Zhao, Ming‐He Mo, Tao Li

2025Environmental Technology & Innovation5 citationsDOIOpen Access PDF

Abstract

Tailings-contaminated soils represent an underutilized land resource, and reclaiming them with forage grasses can restore landscapes, mitigate metal pollution, and support phytoremediation. This study evaluates five forage grasses for reclamation in contaminated tailings soil. All grasses demonstrated strong adaptability, likely due to their metal exclusion traits, with bioconcentration factors (BCF) < 0.11 ± 0.02 for Cd, Pb, and Zn. Grass reclamation significantly improved soil multifunctionality, enhancing physicochemical properties, enzyme activities, and rhizosphere bacterial α-diversity and biomass compared with bare soil. Furthermore, grass reclamation reshaped the microbial community, towards a plant-beneficial microbiome, including the enrichment nitrogen-cycling bacteria (e.g., increased bacteria containing nirK , nosZ genes), and a rise in symbiotic mycorrhizal fungi. Greenhouse experiments further demonstrated that the microbial communities naturally restored in the rhizosphere, similar to those associated with established AMF symbioses, improved forage grass adaptability. These microbial communities facilitated heavy metal stabilization in roots, reduced metal translocation, and lowered the risk of food chain contamination, thereby promoting plant growth. Our results suggest that these naturally restored microbiotas should be prioritized in tailings soil reclamation with forage grasses as an alternative to AMF. However, the potential risk of heavy metal contamination in forage grasses requires careful consideration, as all species investigated pose a risk of exceeding heavy metal limits, except for P. purpureum 'Sweet', remaining within permissible levels for silage. Combining microbial heavy metal mitigation with strategies such as soil amendments and selecting low-metal-accumulating grasses, like, P. purpureum 'Sweet', provides a promising, sustainable approach for phytomanagement of severely contaminated tailings soils. • Five forage grasses adapt well to polluted tailings by excluding heavy metals. • Forage grasses boost soil multifunctionality via improved properties and enzyme activities • Forage grasses restore tailings soil microbiomes, diversity, biomass, and structure. • Naturally restored microbial enhance plant growth and tailings adaptability. • P. purpureum “Sweet” is ideal for reclamation with low metal uptake and strong remediation potential.

Topics & Concepts

TailingsForageEnvironmental remediationEnvironmental scienceAgronomySoil contaminationSoil remediationContaminationAgroforestrySoil waterSoil scienceBiologyEcologyChemistryPhysical chemistrySoil Carbon and Nitrogen DynamicsHeavy metals in environmentElectrokinetic Soil Remediation Techniques
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