Zero-Valent Iron Nanoparticles for Soil and Groundwater Remediation
Abstract
:1. Introduction
2. Zero-Valent Iron
3. Zero-Valent Iron Nanoparticles and Nanoremediation
3.1. Bimetallic Iron-Based Nanoparticles
Pilot and Full-Scale Test for Bimetallic Iron-Based Nanoparticles
3.2. Emulsified Zero-Valent Iron
Pilot and Full-Scale Test for Emulsified Zero-Valent Iron
3.3. Polymer Coated NZVI Particles
3.3.1. NZVI Coated with Synthetic Polymers
3.3.2. NZVI Coated with Natural Polymers
3.3.3. Pilot and Full-Scale Test for Polymer Coated NZVI Particles
4. Limitations and Risks Derived from NZVI Nanoremediation
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviation
·OH | hydroxyl radical |
124TCB | 1,2,4-trichlorobenzene |
2,3,7,8-TCDD | 2,3,7,8-tetraclorodibenzo-p-dioxine |
BDE-209 | decabromodiphenyl ether |
BDE-47 | 2,2′,4,4′-tetrabromodiphenyl ether |
BMP | bimetallic iron-based nanoparticle |
cis-DCE | cis-dichloroethylene |
CMC | carboxymethylcellulose |
DDT | Dichlorodiphenyltrichloroethan |
DNAPL | dense non-aqueous liquid phase |
EZVI | emulsified iron nanoparticles |
GG | guar gum |
MCB | monochlorobenzene |
n/a | Not available |
NZVI | Nanoscale zero-valent iron |
OMA | Olefin maleic acid |
PAA | Poly(acrylic acid) |
PAH | polycyclic aromatic hydrocarbons |
PAM | polyacrylamide |
PAS | polyaspartate |
PCB | polychlorinated biphenyl |
PCE | Tetrachloroethylene or Perchloroethylene |
PEG | polyethylen glycol |
PMMA | poly(methacrylic acid) |
PRB | permeable reactive barrier |
PSS | polystyrene sulfonate |
PTHF | polytetrahydrofuran |
PV3A | polyvinyl alcohol-co-vinyl acetate-co-itaconic acid |
PVP | polyvinylpyrrolidone |
TC | tetracycline |
TCA | trichloroethane |
TCC | Triclocarban |
TCE | trichloroethylene |
TNT | 2,4,6-trinitrotoluene |
trans-DCE | trans-dichloroethylene |
VC | vinyl chloride |
VOC | Volatile organic compound |
VOCl | Volatile organic chlorides |
XG | xanthan gum |
ZVI | Zero-valent iron |
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Pollutants | NZVI Based Treatment | Reference |
---|---|---|
Heavy metals and metalloids | ||
As | NZVI | [40,41,42] |
Pb + Zn | NZVI | [43] |
Pb | NZVI + citric acid | [44] |
Cr(VI) | NZVI/Cu; NZVI/biochar; starch stabilized NZVI | [45,46,47,48] |
Pb + Cd + Cr | NZVI + activated carbon | [48] |
Sb(V) | NZVI + humic acid coated; NZVI | [49] |
U | NZVI | [50] |
Hg | NZVI | [51] |
Ni | NZVI | [52] |
Ag | NZVI | [52] |
Cd | NZVI | [51] |
Other inorganic compounds | ||
Perchlorate | NZVI | [51] |
Nitrate | NZVI | [51] |
Organic compounds (pesticides, polychlorinated hydrocarbons, chlorobenzenes, colouring agents, etc.) | ||
PAHs | NZVI; NZVI + SDS | [42,53,54,55] |
TCE | CMC-NZVI | [56] |
TCE + PCB | Starch-stabilized Fe/Pd | [57] |
Ibuprofen | NZVI | [58] |
DDT | NZVI | [59,60] |
TNT | NZVI | [61] |
2,3,7,8-TCDD | NZVI + Tween 80 | [62] |
TCC | NZVI | [51] |
Bromoform | NZVI | [51] |
Chloroform | NZVI | [51] |
Dibromochloromethane | NZVI | [51] |
Dichloromethane | NZVI | [51] |
Dichlorobromomethane | NZVI | [51] |
Chloromethane | NZVI | [51] |
N-nitrosodimethylamine | NZVI | [52] |
Hexachlorobencene | NZVI | [52] |
PCB | NZVI + saponin | [63] |
DDT | NZVI | [52] |
Lindane | NZVI | [64,65] |
Pentachlorophenol | NZVI | [52] |
Chrysoidin | NZVI | [51] |
Tropaeolin O | NZVI | [51] |
Components | Contaminant | Reference |
---|---|---|
Fe/Pd | Chlorobenzenes | [75] |
Fe/Pd | Polychlorinated biphenyls (PCB) | [76,77] |
Fe/Pd and Fe/Ni | Chlorinated aliphatics (PCE, TCE, VC, …) | [28,59,78,79] |
Fe/Pd and Fe/Ni | Polybrominated diphenyl ethers (PBDEs) | [80,81] |
Fe/Cu, Fe/Al and Fe/Ni | Chromium, Copper | [45,82,83] |
Fe/Pd, Fe/Zn and Fe/Ni | Dyes (Orange G, Congo red, Orange II, …) | [84,85,86,87,88] |
Fe/Ni | Tetracycline | [89] |
Fe/Ni | Triclosan | [82] |
Pollutants | Concentration Decrease | Addition Method | Site | Comments | Time for Study | Reference |
---|---|---|---|---|---|---|
TCE | 96% | Gravity-fed | Groundwater | High dosage of BNPs needed | n/a | [99] |
PCE, TCE; Others | n/a | n/a | Soil and groundwater | n/a | n/a | [98] |
VOCs | 74% | n/a | n/a | n/a | Six months | [98] |
VOCs (ethane, TCE, TCA, DCE, DCA) | 65–96% | Gravity-fed and recirculate | Groundwater | Pd/Fe BNPs | 1 year | [101] |
VC | 50–99% | Injection | Groundwater | Pd/Fe BNPs | Six months | [102] |
Pollutants | Concentration Decrease | Addition Method | Site | Comments | Location | Reference |
---|---|---|---|---|---|---|
TCE, TCA, DCE, DCA | TCE and TCA > 65–96% | Gravity-fed and recirculate | groundwater | Polymer coated nanoparticles | Naval Air Station Jacksonville (FL, USA) | [101] |
PCE, TCE | PCE > 85% TCE > 85% | Pneumatic injection, direct injection | groundwater | Uncertainties in the estimations | Parrick Island (SC, USA) | [109] |
TCE | TCE > 80 (DNAPL) TCE > 60% (groundwater) | n/a | DNAPL, groundwater | n/a | Cape Canaveral Air Force Station (FL, USA) | [105] |
TCE | TCE > 95% | n/a | n/a | n/a | Patrick Air Force Base (FL, USA) | [110] |
Chlorinated VOCs | >86% | Pneumatic injection | Soil and groundwater | 2.5 years monitoring | Marine Corps Recruit Depo. Parris Island (SC, USA) | [111] |
Coated Polymer | Improvement | Contaminant | Reference |
---|---|---|---|
Synthetic Polymers | |||
PAA | Transportability | TCE, Lindane | [64,66] |
PV3A | Stability | TCE | [119] |
PEG | Stability | Lindane | [65] |
PTHF | Stability | Lindane | [65] |
PVP | Stability | TC, TCE | [120,121,122] |
PSS | Stability | n/a | [123,124,125] |
PAM | Stability | n/a | [123] |
PMAA-b-PMMA-b-PSS | Stability | TCE | [124,126] |
OMA | Transportability | n/a | [127] |
Natural Polymers | |||
CMC | Stability, Transportability | TCE, PCB, Lindane, Cr(VI) | [64,100,122,125,128,129] |
PAS | Stability | Lindane | [64,125] |
XG | Stability, Transportability | n/a | [116,130] |
GG | Stability, Reactivity | TCE | [116,122] |
Pollutants | Conc. Decrease | Addition Method | Site | Comments | Location | Reference |
---|---|---|---|---|---|---|
Chlorinated compounds | >90% | Injection in two phases | 30 days | Hamilton Township, New Jersey (USA) | [32] | |
TCA, DCE, TCE, PCE | 80–90% | n/a | Soil | n/a | Naval Air Engineering Station of Lakehurst (USA) | [98] |
TCA, DCE, TCE, PCE | 80–90% | n/a | Soil | n/a | Naval Air Station of Jacksonville (USA) | [98] |
PCE | 90% | n/a | Soil | 2 years after, more reduction | Bornheim, Germany (Europe) | [137] |
PCE, TCE, DCE | 60–75% for Horice and 90% for Pisecna | Injection (82 injection wells) | Soil | n/a | Czech Republic (Horice and Pisecna) | [137] |
Chlorinated compounds | >90% | n/a | n/a | 30 days | Hamilton Township, New Jersey (USA) | [32] |
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Galdames, A.; Ruiz-Rubio, L.; Orueta, M.; Sánchez-Arzalluz, M.; Vilas-Vilela, J.L. Zero-Valent Iron Nanoparticles for Soil and Groundwater Remediation. Int. J. Environ. Res. Public Health 2020, 17, 5817. https://doi.org/10.3390/ijerph17165817
Galdames A, Ruiz-Rubio L, Orueta M, Sánchez-Arzalluz M, Vilas-Vilela JL. Zero-Valent Iron Nanoparticles for Soil and Groundwater Remediation. International Journal of Environmental Research and Public Health. 2020; 17(16):5817. https://doi.org/10.3390/ijerph17165817
Chicago/Turabian StyleGaldames, Alazne, Leire Ruiz-Rubio, Maider Orueta, Miguel Sánchez-Arzalluz, and José Luis Vilas-Vilela. 2020. "Zero-Valent Iron Nanoparticles for Soil and Groundwater Remediation" International Journal of Environmental Research and Public Health 17, no. 16: 5817. https://doi.org/10.3390/ijerph17165817
APA StyleGaldames, A., Ruiz-Rubio, L., Orueta, M., Sánchez-Arzalluz, M., & Vilas-Vilela, J. L. (2020). Zero-Valent Iron Nanoparticles for Soil and Groundwater Remediation. International Journal of Environmental Research and Public Health, 17(16), 5817. https://doi.org/10.3390/ijerph17165817