Phytoremediation: a sustainable environmental technology for heavy metals decontamination

Toxic metal contamination of soil is a major environmental hazard. Chemical methods for heavy metal's (HMs) decontamination such as heat treatment, electroremediation, soil replacement, precipitation and chemical leaching are generally very costly and not be applicable to agricultural lands. Ho...

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Bibliographic Details
Published inSN applied sciences Vol. 3; no. 3; p. 286
Main Author Nedjimi, Bouzid
Format Journal Article
LanguageEnglish
Published Cham Springer International Publishing 01.03.2021
Springer Nature B.V
Subjects
2. Earth and Environmental Sciences (general)
Agricultural land
Applied and Technical Physics
Chemistry/Food Science
Clean technology
Contamination
Decontamination
Earth Sciences
Engineering
Environment
Environmental hazards
Flowers & plants
Genetic engineering
Heat treatment
Heat treatments
Heavy metals
Inoculation
Leaching
Materials Science
Metabolism
Microorganisms
Nanoparticles
Phytoremediation
Plant growth
Plant hormones
Plant species
Pollutants
Polluted environments
Precipitation heat treatment
Review Paper
Selenium
Soil chemistry
Soil contamination
Soil pollution
Soils
Toxicity
China
Germany
Hyper-accumulator plants
PGR
PGPB
Transgenic plants
Heavy metals
Phytoremediation
Nanoparticles (NPs)
Online AccessGet full text

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Abstract Toxic metal contamination of soil is a major environmental hazard. Chemical methods for heavy metal's (HMs) decontamination such as heat treatment, electroremediation, soil replacement, precipitation and chemical leaching are generally very costly and not be applicable to agricultural lands. However, many strategies are being used to restore polluted environments. Among these, phytoremediation is a promising method based on the use of hyper-accumulator plant species that can tolerate high amounts of toxic HMs present in the environment/soil. Such a strategy uses green plants to remove, degrade, or detoxify toxic metals. Five types of phytoremediation technologies have often been employed for soil decontamination: phytostabilization, phytodegradation, rhizofiltration , phytoextraction and phytovolatilization . Traditional phytoremediation method presents some limitations regarding their applications at large scale, so the application of genetic engineering approaches such as transgenic transformation, nanoparticles addition and phytoremediation assisted with phytohormones, plant growth-promoting bacteria and AMF inoculation has been applied to ameliorate the efficacy of plants as candidates for HMs decontamination. In this review, aspects of HMs toxicity and their depollution procedures with focus on phytoremediation are discussed. Last, some recent innovative technologies for improving phytoremediation are highlighted.
AbstractList Toxic metal contamination of soil is a major environmental hazard. Chemical methods for heavy metal's (HMs) decontamination such as heat treatment, electroremediation, soil replacement, precipitation and chemical leaching are generally very costly and not be applicable to agricultural lands. However, many strategies are being used to restore polluted environments. Among these, phytoremediation is a promising method based on the use of hyper-accumulator plant species that can tolerate high amounts of toxic HMs present in the environment/soil. Such a strategy uses green plants to remove, degrade, or detoxify toxic metals. Five types of phytoremediation technologies have often been employed for soil decontamination: phytostabilization, phytodegradation, rhizofiltration, phytoextraction and phytovolatilization. Traditional phytoremediation method presents some limitations regarding their applications at large scale, so the application of genetic engineering approaches such as transgenic transformation, nanoparticles addition and phytoremediation assisted with phytohormones, plant growth-promoting bacteria and AMF inoculation has been applied to ameliorate the efficacy of plants as candidates for HMs decontamination. In this review, aspects of HMs toxicity and their depollution procedures with focus on phytoremediation are discussed. Last, some recent innovative technologies for improving phytoremediation are highlighted.
Toxic metal contamination of soil is a major environmental hazard. Chemical methods for heavy metal's (HMs) decontamination such as heat treatment, electroremediation, soil replacement, precipitation and chemical leaching are generally very costly and not be applicable to agricultural lands. However, many strategies are being used to restore polluted environments. Among these, phytoremediation is a promising method based on the use of hyper-accumulator plant species that can tolerate high amounts of toxic HMs present in the environment/soil. Such a strategy uses green plants to remove, degrade, or detoxify toxic metals. Five types of phytoremediation technologies have often been employed for soil decontamination: phytostabilization, phytodegradation, rhizofiltration , phytoextraction and phytovolatilization . Traditional phytoremediation method presents some limitations regarding their applications at large scale, so the application of genetic engineering approaches such as transgenic transformation, nanoparticles addition and phytoremediation assisted with phytohormones, plant growth-promoting bacteria and AMF inoculation has been applied to ameliorate the efficacy of plants as candidates for HMs decontamination. In this review, aspects of HMs toxicity and their depollution procedures with focus on phytoremediation are discussed. Last, some recent innovative technologies for improving phytoremediation are highlighted.
ArticleNumber 286
Author Nedjimi, Bouzid
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  orcidid: 0000-0003-2049-7352
  surname: Nedjimi
  fullname: Nedjimi, Bouzid
  email: bnedjimi@yahoo.fr
  organization: Laboratory of Exploration and Valorization of Steppe Ecosystem, Faculty of Science of Nature and Life, Ziane Achour University of Djelfa
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PGR
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Snippet Toxic metal contamination of soil is a major environmental hazard. Chemical methods for heavy metal's (HMs) decontamination such as heat treatment,...
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SubjectTerms 2. Earth and Environmental Sciences (general)
Agricultural land
Applied and Technical Physics
Chemistry/Food Science
Clean technology
Contamination
Decontamination
Earth Sciences
Engineering
Environment
Environmental hazards
Flowers & plants
Genetic engineering
Heat treatment
Heat treatments
Heavy metals
Inoculation
Leaching
Materials Science
Metabolism
Microorganisms
Nanoparticles
Phytoremediation
Plant growth
Plant hormones
Plant species
Pollutants
Polluted environments
Precipitation heat treatment
Review Paper
Selenium
Soil chemistry
Soil contamination
Soil pollution
Soils
Toxicity
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Title Phytoremediation: a sustainable environmental technology for heavy metals decontamination
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