Next Article in Journal
Advanced Drinking Groundwater As Phytofiltration by the Hyperaccumulating Fern Pteris vittata
Next Article in Special Issue
A New Polyvinylidene Fluoride Membrane Synthesized by Integrating of Powdered Activated Carbon for Treatment of Stabilized Leachate
Previous Article in Journal
Time Evolution Study of the Electric Field Distribution and Charge Density Due to Ion Movement in Salty Water
Previous Article in Special Issue
Treatment of Poultry Slaughterhouse Wastewater with Membrane Technologies: A Review
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Water
Volume 13
Issue 16
10.3390/w13162186
water-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Recent Advances of Nanoremediation Technologies for Soil and Groundwater Remediation: A Review

by
Motasem Y. D. Alazaiza
1,*,
Ahmed Albahnasawi
2,
Gomaa A. M. Ali
3,
Mohammed J. K. Bashir
4,
Nadim K. Copty
5,
Salem S. Abu Amr
6,
Mohammed F. M. Abushammala
7 and
Tahra Al Maskari
1
1
Department of Civil and Environmental Engineering, College of Engineering, A’Sharqiyah University, Ibra 400, Oman
2
Department of Environmental Engineering-Water Center (SUMER), Gebze Technical University, Kocaeli 41400, Turkey
3
Chemistry Department, Faculty of Science, Al-Azhar University, Assiut 71524, Egypt
4
Department of Environmental Engineering, Faculty of Engineering and Green Technology (FEGT), Universiti Tunku Abdul Rahman, Kampar 31900, Malaysia
5
Institute of Environmental Sciences, Bogazici University, Istanbul 34342, Turkey
6
Faculty of Engineering, Demir Campus, Karabuk University, Karabuk 78050, Turkey
7
Department of Civil Engineering, Middle East College, Knowledge Oasis Muscat, Muscat 135, Oman
*
Author to whom correspondence should be addressed.
Water 2021, 13(16), 2186; https://doi.org/10.3390/w13162186
Submission received: 29 May 2021 / Revised: 1 August 2021 / Accepted: 5 August 2021 / Published: 10 August 2021
(This article belongs to the Special Issue Wastewater Treatment: Current and Future Techniques)
Browse Figures
Versions Notes

Abstract

:
Nanotechnology has been widely used in many fields including in soil and groundwater remediation. Nanoremediation has emerged as an effective, rapid, and efficient technology for soil and groundwater contaminated with petroleum pollutants and heavy metals. This review provides an overview of the application of nanomaterials for environmental cleanup, such as soil and groundwater remediation. Four types of nanomaterials, namely nanoscale zero-valent iron (nZVI), carbon nanotubes (CNTs), and metallic and magnetic nanoparticles (MNPs), are presented and discussed. In addition, the potential environmental risks of the nanomaterial application in soil remediation are highlighted. Moreover, this review provides insight into the combination of nanoremediation with other remediation technologies. The study demonstrates that nZVI had been widely studied for high-efficiency environmental remediation due to its high reactivity and excellent contaminant immobilization capability. CNTs have received more attention for remediation of organic and inorganic contaminants because of their unique adsorption characteristics. Environmental remediations using metal and MNPs are also favorable due to their facile magnetic separation and unique metal-ion adsorption. The modified nZVI showed less toxicity towards soil bacteria than bare nZVI; thus, modifying or coating nZVI could reduce its ecotoxicity. The combination of nanoremediation with other remediation technology is shown to be a valuable soil remediation technique as the synergetic effects may increase the sustainability of the applied process towards green technology for soil remediation.

1. Introduction

Contaminated soil and groundwater, especially in industrialized and urban areas, is a widespread problem that presents extreme risks to the environment and humans [1,2]. Numerous studies have focused on the remediation of soil, groundwater, wastewater, and landfill leachate polluted by various contaminants [3,4]. Soil and groundwater remediation can be broadly classified according to the place of remediation, which can be ex situ or in situ. For ex situ remediation, the polluted soil or groundwater is recovered from the subsurface and treated on the same site or transferred to another site for treatment [5]. In contrast, in situ remediation is when the contaminated soil or groundwater is remediated directly in the subsurface. The in situ remediation process is often preferred because it is cheaper than the ex situ remediation process [2,6]. For example, according to Chany et al. [7], the remediation cost of removal and replacement of contaminated soil is very expensive (on the order of $3 million/ha), which is considered a big challenge for developing countries in terms of environmental sustainability practice [7].
Reducing pollution to a desirable and safe level is the main target of soil and groundwater remediation processes. Physical, chemical, and biological technologies have been used to achieve this goal for soil and groundwater remediation. In general, several factors play a significant role in the selection of the optimal soil and groundwater remediation, including soil properties and contaminants and the nature of selected and designed remediation technology [8]. Conventional methods such as pump-and-treat involve pumping groundwater by wells and removal of contaminants from the extracted groundwater by ex situ methods such as carbon adsorption, air stripping, chemical oxidation/precipitation, or biological reactors. However, these methods are associated with high operating costs and contaminated waste production [4]. For groundwater and soil contaminated with organic contaminants in the form of dense nonaqueous phase liquids (DNAPLs), emergent remediation technology such as surfactant enhanced remediation (SER) has been shown to be effective. Nevertheless, these technologies are associated with risks; with the decrease in interfacial force of DNAPLs, uncontrolled vertical movement may occur [9].
In recent years, nanotechnology has been increasingly considered in a broad range of fields. Nanoparticles (NPs) have many essential and promising properties due to their enabled functions in many sectors [10,11,12,13]. NPs are produced by combining multidisciplinary fields such as molecular level manufacturing principles and engineering. Generally, nanotechnology is a technique that constructs particles in a size range of 1–100 nanometers, studies the physical phenomena related to those particles and applying these in many sectors [4]. Nanotechnology is being used in many sectors such as the chemical, electrical, biomedical, and biotechnology industries. While many industries produce and use various forms of nanomaterials, there are many attempts to use nanotechnology for environmental protection activities such as water and wastewater treatment, pollution control, and treatment/remediation of contaminated soil and groundwater [14].
Technologies that apply nanoremediation for contaminated sites have been used in recent years (2009 till now). Studies conducted to evaluate nanoremediation technologies are mostly bench-scale with few field-scale applications [2]. The main advantages of using nanoremediation for soil and groundwater remediation, especially for extensive site cleaning, are reduced cost and cleanup time, complete degradation of some contaminants without the need for the disposal of polluted soil and without the need to transfer the soil or pump groundwater [14,15].
Nanoremediation technologies involve the use of reactive NPs for conversion and detoxification of contaminants. The main mechanisms for remediation by NPs are catalysis and chemical reduction [14,16]. In addition, adsorption is another removal mechanism facilitated by the NPs since NPs have high surface-area-to-mass ratios and different distribution of active sites, increasing the adsorption ability [17]. Many engineering NPs have highly feasible characteristics for in situ remediation applications due to their innovative surface coating and minute size. In addition, NPs can diffuse and penetrate the tiny spaces in the subsurface and be suspended in groundwater for a long time; compared to microparticles, NPs can potentially travel long distances and achieve larger spatial distribution [14].
The physical movement of NPs and/or transport in groundwater is dominated by random motion or Brownian movement rather than the wall effect as a result of their nanoscale characteristics [18]. Thus, compared to microscale particles, which are strongly influenced by gravity sedimentation due to their density and large size, the movement of NPs is not controlled by gravity sedimentation, remaining suspended in groundwater during the remediation process. Thus, NPs afford a functional treatment approach allowing direct injection into the subsurface where pollutants are present [14].
Several studies have revealed the potential use of nanoremediation for soil and groundwater [19,20,21,22]. However, the environmental effects of those NPs are still unclear and need more investigation to understand the environmental fate and toxicity of NPs, as these issues are crucial for environmental protection practice.
The use of nanomaterials for soil and groundwater remediation has been widely tested at the laboratory level against a large number of contaminants, offering promising results [23,24]. However, nanomaterials may pose positive or negative impacts on living organisms, the environment, society, and the economy, which should be evaluated in a case-specific context. Appropriate documentation of nanoremediation risks, field-scale validation of remediation results, science–policy interface consultations, and suitable market development initiatives are ways to increase the popularity and acceptability of nanoremediation technologies [25]. Savolainen et al. [26] stated that the fundamental elements of risk assessment are likely to remain and will continue to include the elements designed for other chemicals and particles, notably (1) hazard identification, (2) hazard characterization, (3) exposure assessment, and (4) risk characterization, which are the four steps of the risk assessment process [26]. However, the environmental effects of those NPs are still unclear and need more investigation to understand the environmental fate and toxicity of NPs as these issues are crucial for environmental protection practice [15,27].
Various nanomaterials have been investigated for soil and groundwater remediation, such as metal oxides, nanoscale zeolites, enzymes, carbon nanotubes and fibers, titanium dioxide, and noble metals [14]. Generally, zero-valent iron (nZVI) is most widely used for soil and groundwater remediation as nZVI is considered a suitable electron donor and highly reactive [28]. The use of these different nanomaterials will be discussed in detail in this review.
The main objective of this review is to present the recent studies and development regarding the application of nanotechnology for the remediation of soil and groundwater that are contaminated by a wide range of compounds such as hydrocarbons and heavy metals. The focus is primarily on the developments of the last decade, which has witnessed a substantial increase relating in the number of studies examine nanotechnology for the remediation of soil and groundwater. The potential impact of NP use on the environment is also presented and discussed. Finally, the feasibility of combining nanoremediation with other remediation technologies is also discussed.

2. Relationship between Soil and Groundwater: Contaminants and Remediation

Soil and groundwater are susceptible to pollution by a wide array of pollutants such as petroleum hydrocarbon, chlorinated solvents, and heavy metals. [29]. Selecting a proper remediation technology for a contaminated environment usually depends on contaminant characteristics and contaminated site characteristics such as physical, chemical, and biological properties. All these factors should be considered during the remediation process, design, and implication. Moreover, the time/cost constraints, the regulatory requirements, and the remediation mechanisms should be considered in the selection process.
Nevertheless, adopting risk-based management approaches is increasingly a focus of environmental researchers due to the high demand for sustainable responses to environmental pollutions [14,30]. The polluted environments are usually surface water, sediments, soil, and groundwater, which are mainly contaminated with low and high molecular weight petroleum hydrocarbon compounds, semi-volatile organic compounds, volatile organic compounds, polycyclic aromatic hydrocarbons (PAHs), polychlorinated biphenyls, persistent organic pollutants, organochlorinated pesticides, NAPL, hydrophobic organic compounds, heavy metals, and xenobiotics [31,32,33]. These pollutants may migrate or spread far from the source and seriously affect flora, fauna, and the ecosystem [30]. Managing the polluted environments requires the selection of the proper remediation technology for the pollutants, destruction, and separation methods according to many ex situ and in situ remediation methods for surface water, sediments, soil, and groundwater comprising physicochemical, biological, chemical, thermal, electromagnetic, electric, and ultrasonic remediation technologies [34,35,36]. Remediation in an aqueous environment includes remediation of groundwater and surface water polluted by contaminants, whereas soil remediation includes remediation of sediment subsoil and topsoil polluted by contaminates [37]. Soil and groundwater remediation could be conducted separately or together, depending on the concentration of contaminants and the extent of pollution. The efficiency of remediation technology depends on the design and implication based on the characteristics of polluted soil and the remediation technique. Combining one remediation technology with others sequentially or simultaneously may enhance the overall remediation process through combined or synergistic effects [38].

3. Nanomaterials

NPs are particles with a dimension between 1 and 100 nm, whereas nanomaterials are materials with a dimension of 100 nm or less in one dimension at least [39,40,41,42,43,44,45,46]. NPs have many reaction/adsorption sites on their surface due to the large proportion of atoms [10,47]. This unique property makes NPs highly reactive with surrounding contaminants cumbered to the composition materials in the macro scale [2]. Nanomaterials can be classified as natural or manufactured. Clay, iron oxide, and organic matter are examples of naturally occurring NPs in soil composition. Manufactured NPs are either developed or synthesized with a unique property to enhance their industrial or technological applications [32,48,49,50]. Generally, nanomaterials can be produced by two methods; the first method is from outside to inside or from top to bottom, whereby a significant part transfers into the minor parts. The second method is from bottom to top, whereby small parts are buildup into more extensive parts [51].
Several nanomaterials have been developed for contaminant remediation, such as nZVI, nanoscale zeolites, carbon nanotubes, metal oxides, bimetallic nanoparticles (BNPs), enzymes, and titanium dioxide (TiO2) [52,53,54,55,56,57]. Soil remediation using these three nanoremediation materials (nZVI, TiO2, and CNTs) can be found in [58].
The unique characteristics of the nanomaterials, such as high surface area, quantum size effect, ease of separation and recycling, etc., support their usage as adsorbents. For example, the ferromagnetism of iron-doped nanomaterials supports their recycling and reuse [11,59]. The potential for nanomaterials recyclability makes them economically attractive. The hydrophobicity of fullerene is the key factor for its adsorption properties and ease of recycling [60].

4. Nanoremediation

Many researchers have focused on the use and development of nanoremediation technologies for soil and groundwater remediation [4]. Nanoremediation is considered an eco-friendly technology. As a result, it is considered a feasible choice for conventional site remediation technology [4,17,61].
Nanoremediation may provide a cost-effective and faster solution for site remediation. Various NPs have been used for nanoremediation, such as metal oxides, nanoscale zeolites, nanometals, carbon nanotubes, and titanium dioxide. In this section, recently published studies relating to soil and groundwater remediation using four nanotechnologies are presented. The four technologies are nanoscale nZVI, carbon nanotube, metal nanoparticle, and magnetic nanoparticle.

4.1. Soil Nanoremediation

The first implementation of NPs on the field scale for soil and groundwater remediation was reported 20 years ago and revealed that NPs could remain active in injected soil for up to 56 days and move with groundwater for more than 20 m [62]. Zhang et al. [62] reported that more than 99% of trichloroethene (TCE) could be removed from contaminated sites within a few days.

4.1.1. Nanoscale Zero-Valent Iron

Injection of nZVI is well-suited to soil remediation because of its limited disruption to the environment, fast kinetics, cost-effectiveness, and non-toxic nature [63]. According to Karn et al. [63], the first synthesis and use of nZVI were reported in the 1990s. Iron nanoscale was synthesized from Fe2+ and Fe3+ to produce particles ranging from 10 to 100 nm [14]. nZVI was used to remove many contaminants from water, mainly halogenated organic compounds that usually contaminate soil and groundwater. They reported for the first time the effectiveness of using nZVI for detoxification and transformation of many environmental contaminants such as chlorinated organic solvents, polychlorinated biphenyls, and organochlorine pesticides.
Moreover, the authors also showed that modifying nZVI may increase process speed and efficiency. In a recent study, Tian et al. [64] characterized and investigated the application of polyvinylpyrrolidone (PVP)-enhanced nZVI to remediate TCE-contaminated soil [64]. The results showed that the size of prepared PVP-nZVI was around 70 nm when the isoelectric point was around 8.5. In terms of TCE removal efficiency of the investigated system, the removal of TCE was around 84.73%. They concluded that the PVP-nZVI technology was promising to remediate TCE-contaminated soil. Subsequently, Reginatto et al. [65] investigated the performance of nZVI for the removal of hexavalent chromium (Cr(VI)) from clayey residual soil [65]. Five different nZVI materials to contaminant ratios were used, and three different nZVI injections pressure were applied. The result showed that the ratio between nZVI and Cr(VI) significantly affected removal efficiency. The removal efficiency at (1000/11) mg mg−1 ratio was 98%, whereas at (1000/140) mg mg−1, it was 18%. As the pressure increased, the contaminant leaching increased; thus, the pressure of 30 kPa was more efficient.
In another study, Shubair et al. [66] investigated nitrate removal in porous media using nZVI and modified nZVI using Cu in upflow packed sand column containing a multilayer system [66]. The results revealed the optimal condition for high nitrate removal when 10 cm of nZVI/sand was used, where the nitrate removal efficiency was around 97%. On the other hand, for Cu-modified nZVI/sand, the best condition was noted when a double 5 cm layer was used, where complete nitrate removal was observed. The result suggests that using nZVI in a single layer or Cu-modified nZVI in a multilayer could achieve high nitrate removal. In a subsequent study, Xue et al. [67] investigated the performance of rhamnolipid modified nZVI (R-nZVI) to reduce lead (Pb) and cadmium (Cd) in river sediments by immobilization [67]. They demonstrated that after 42 days, R-nZVI transformed unstable Pb and Cd to stable fractions as the residual percentage of Pb and Cd increased to reach 43.10 and 56.40%, respectively. In a recent study, Blundell and Owens [19] investigated the performance of nZVI for 1,1,1-Trichloro-2,2-bis(4-chlorophenyl) ethane (DDT) removal from contaminated soil [19]. They compared the efficacy of nZVI to microscale zero-valent (µZVI). They found that samples treated with nZVI showed around 85% reduction in DDT concentration, whereas about 11% reduction in DDT was observed when µZVI was used. The result clearly shows the superiority of using nZVI over µZVI on DDT removal from contaminated soil. Table 1 summarizes the main results of the recent studies conducted for soil remediation by nanoremediation technologies. The mechanism of metal ions removal using nZVI which involve reduction, oxidation, adsorption and/or precipitation, as shown in Figure 1 [19].

4.1.2. Carbon Nanotubes

Since the beginning of their application in the water treatment industry, carbon nanotubes (CNTs) have received significant attention from many researchers due to their superior properties, especially their adsorption properties, since CNTs have a strong ability to be attached to the functional groups of pollutants [79]. CNTs can be classified as single-walled carbon tubes and multi-walled carbon nanotubes.
Many studies have been carried out to investigate the performance of CNTs in terms of soil and groundwater remediation. One such attempt has been conducted by Apul et al. [68], who evaluated the performance of microwave-assisted CNTs for removing total petroleum hydrocarbons (TPH) from the soil [68]. Results showed that after using microwave treatment for 60 s, an 82% removal efficiency of TPH was achieved. Zhang et al. [69] assessed the remediation of Cr(VI) contaminated soil using carboxylate or hydroxylated multi-walled carbon nanotubes (MWCNT-COOH or MWCNT-OH) [69]. In addition, the effect of their catalytic activity on the reduction of Cr(VI) by citric acid was evaluated. The results showed that at pH 5, Cr(VI) adsorption capacity was 8.09 and 7.85 mg g−1 by MWCNTs-COOH and MWCNT-OH, respectively. In a subsequent study, Cheng et al. [70] studied the efficiency of modified carbon black NPs (MCBN) for petroleum biodegradation and heavy metal immobilization in contaminated soil remediated by plant–microbe combined remediation [70]. The result showed that 65% of petroleum degradation increased in petroleum-Ni co-contaminated soil, whereas in petroleum-Cd co-contaminated soil, the increase in petroleum degradation was 50%. Moreover, the result showed that heavy metals’ availability could significantly decrease by using MNCB in Cd- and Ni-contaminated soil, leading to enhancing the plant’s growth.
In another study, Gong et al. [80] investigated the performance of single-walled carbon nanotubes (SWCNTs) and multi-walled carbon nanotubes (MWCNTs) for the reduction of dichlorobiphenyls- chloroethane (DDT) and hexachlorocyclohexane (HCH) [80]. The authors used different concentrations of SWCNTs and MWCNTs as well as different remediation times. The result showed that CNTs could effectively treat DDTs and HCHs. Optimum conditions for the SWCNTs were 0.29 wt% dosages for 4 months. In addition, the results suggest that the efficiency of CNTs remediation was highly dependent on dosage and sediment–sorbent contact time. Abbasian et al. [72] used MWCNTs to enhance the bioremediation of crude oil-contaminated soil [72]. They mixed different concentrations of crude oil with MWCNTs for 30 days, and then the microbial diversity of these samples was identified by fluoxetine (FLX) pyrosequencing. The results revealed that using MWCNTs can enhance the degradation of hydrocarbons by increasing the total microbial population. MWCNTs were also used to examine the performance of carbon materials to remediate DDTs and HCHs from sediment. The results showed that sediment remediated with 2 wt% activated carbon (AC) and MWCNTs showed 93% and 59% decrease for DDTs, respectively, and 97% and 75% for HCHs in aqueous equilibrium [73]. The results suggest that the AC was more effective than MWCNTs due to its great specific surface area. These findings revealed the promising of using carbon materials as in situ soil remediation.

4.1.3. Metal and Magnetic Nanoparticles

The use of metal NPs to remediate and immobilize the contaminant from soil and groundwater has attracted much attention recently [74]. Many recent studies examined the performance of using metal NPs for soil remediation. One such attempt has been presented by Peikam and Jalali [74], who studied the remediation of Zn, Ni, and cadmium (Cd) from two contaminated non-calcareous and calcareous soils by SiO2 NPs [74]. The result showed that the reduction of Cd was maximum with 3% SiO2 (56.1%) and 1% Al2O3 (38.3%) for the calcareous and non-calcareous soils, respectively. In terms of Zi, the highest reduction in calcareous and non-calcareous soil was 57.1% for 3% TiO2 and 28.8% for 3.0% Al2O3. In an earlier study, Qiao et al. [75] examined the performance of biochar-supported iron phosphate NPs stabilized by a sodium carboxymethyl cellulose composite for Cd remediation from contaminated soil [75]. A batch experiment with composite (soil-to-solution ratio 1 g: 10 mL) was used. The results indicated that after 25 days, 81.3% of Cd was reduced. The results suggest that the investigated composite could enhance the immobilization of Cd in soil by reducing bioaccessibilty and leachability. In a recent study, Baragano et al. [76] compared the performance of goethite nanospheres (nGoethite) and nZVI for contaminated soil remediation [76]. The result showed that for 2% nZVI dosage, the decrease was 89.5%. The soil phytotoxicity was reduced in general, and the soil parameters were not negatively affected by using nZVI to remediate the contaminated soil. On the other hand, the use of nGoethite showed an excellent result as a small dosage of nGoethite (0.2%) could decrease the As by 82.5%. However, at high dosage, the soil phytotoxicity increased as the electrical conductivity of the soil increased due to using high dosage. The results suggest that both nGoethite and nZVI are promising nanomaterials for As immobilization from contaminated soil.
Environmental remediation using magnetic NPs (MNPs) has received attention recently because of their facile separation using a magnet and special metal-ion adsorption. Several studies investigated the performance of MNPs for soil and groundwater remediation. Fan et al. (2016) examined new MNPs (core–shell Fe3O4@SiO2 NPs coated with iminodiacetic acid chelators) for contaminated soil remediation by non-magnetic heavy metals [77]. The mechanism of removal was chelation and separation by magnetic force. The results indicated that the removal rates of Cd and Pb were 84.9% and 72.2%, respectively. In addition, the results demonstrated that the organic content of the soil negatively affected the removal of the residual heavy metals, whereas the use of MNPs did not change the chemical composition of the soil.

4.2. Groundwater Nanoremediation

The use of NPs in water treatment started in the 1990s and is therefore considered one of the newer technologies. Gillham and Hannesin (1964) were the first researchers to use the idea of using NPs on decontamination of contaminated water. They used nZVI for remediation of the halogenated group [81]. Nevertheless, Wang and Zhang (1997) conducted the first study that used NPs to remediate organo-chlorines from contaminated groundwater. They observed complete and rapid removal of several aromatic chlorinated using bimetallic NPs [82].

4.2.1. Nanoscale Zero-Valent Iron

Since 1997, various nanomaterials have been used for groundwater remediation. However, the application of nZVI for groundwater remediation has received more focus due to their low cost of production and low toxicity [2,63,83]. Figure 2 represents the remediation process by injection of nZVI for DNAPLs. It is reported that nZVI could be used for chlorinated organic compound remediation. Lin et al. (2018) studied the performance of polyethyleneimine (PEI)-coated nZVI (PEI-nZVI) to remediate three DNAPLs (perchloroethene (PCE), trichloroethylene, and 1,2-dichloroethene (1,2-DCE)) by direct injection in the field test [84]. The result showed that after one day of injection, a remarkable reduction in the DNAPLs was recorded. The result showed complete removal (>99%) of the three DNAPLs after one day from the (PEI-nZVI) injection [84]. In a recent study, Chen et al. (2020) investigated the performance of sulfide-modified nZVI (S-nZVI) supported on biochar (BC) for TCE removal from groundwater. In addition, the effect of many factors such as the mass ratio of S-nZVI to BC, pyrolysis temperature of biochar, and initial pH on the TCE removal were examined [20]. The results indicated that the mass ratio of S-nZVI to BC could satisfy the amount of degradation and adsorption of TCE. The pyrolysis temperatures could influence the TCE degradation and adsorption by changing the physicochemical properties of BC. The initial pH had no significant effect on the total TCE removal, whereas the degradation was enhanced at high pH. Moreover, the result showed that within 2 h reaction time, 100% of the TCE was removed at S-nZVI@BC500, where at S-nZVI@BC300 and S-nZVI@BC700, the removal efficiencies of TCE were 79.97% and 86.4%, respectively [20]. In a similar study, Chen et al. [20] studied the effects of Fe/S molar ratio, dissolved oxygen, initial pH, and particle aging on TCE remediations by S-nZVI [20]. The result indicated that Fe/S molar ratio and initial pH remarkably affected the TCE removal, where a higher TCE removal was obtained at Fe/S molar ratio of 60 at pH above 7. A slight decrease in TCE decolorization was observed when S-nZVI was aged up to 20 days, whereas a remarkable decrease was observed at an aging time of 30 days. Finally, dissolved oxygen had a small effect on TCE removal S-nZVI [85]. In another study, Zhu et al. [86] used green technology to synthesize nZVI/Cu from green tea for Cr(VI)-contaminated groundwater remediation [86]. The result showed that the removal efficiency of Cr(VI) was enhanced by decreasing the initial Cr(VI) concentration and initial pH and increasing the temperature, while the presence of humic acids in groundwater decreased the activity of nZVI/Cu. In addition, the result indicated that at optimum conditions (pH = 5, temperature 303 K), the Cr(VI) removal efficiency was 94.7%. Finally, the results suggest that nZVI/Cu is a promising green technology for contaminated groundwater by Cr(VI) [86]. Díaz et al. [21] evaluated the performance of two dosages of commercial nZVI (1 and 5%) for Cu and/or Ni immobilization from water and acidic soil. The results showed that the presence of Cu affected the immobilization of Ni, whereases the presence of Ni did not affect the immobilization of Cu. The efficiency of nZVI was better in water than in soil. The use of 5% dosage completely removed Cu and Ni from water samples, where in soil samples, 5% dosage achieved 54% and 21% embolization for Ni and Cu, respectively [21].

4.2.2. Carbon Nanotubes

In recent years, the use of CNTs for water and groundwater remediation has been increasingly attractive due to their high adsorption affinity. Many recent studies investigated the performance of CNTs for contaminated groundwater remediation. Mpouras et al. [22] investigated Cr(VI) removal from groundwater by MWCNTs. In addition, the effect of operating conditions such as MWCNTs and Cr(VI) concentration, pH, and contact time were examined [22]. The results showed that pH has a significant effect on the adsorption efficiency of MWCNTs; for pH higher than 7, the adsorption process remarkably increased. The adsorption process increased by increasing the MWCNTs concentration. At pH 8, the adsorption percentage increased from 85% to 100% as the concentration of MWCNTs increased from 10 to 50 g L−1 [22]. In another study, Lico et al. [87] examined the performance of MWCNTS for the removal of unleaded gasoline from water [87]. They used a lab-scale experiment by adding 20 mL of unleaded gasoline to 30 mL of water and adding different MWCNTs. The results indicated that a small amount of MWCNTs (0.7 g) could remove within 5 min a high percentage of unleaded gasoline. In another study, Liang et al. [88] investigated the efficiency of using alumina-decorated MWCNTs (Al2O3/MWCNTs) for simultaneous remediations of cadmium (Cd(II)) and TCE from groundwater [88]. They conducted a batch experiment for a wide range of conditions. The result showed that the maximum adsorption capacities achieved by Al2O3/MWCNTs were 19.84 mg g−1 for Cd(II) and 27.21 mg g−1 for TCE. The results suggest that Al2O3/MWCNTs could be a promising technology for Cd(II) and TCE-contaminated groundwater remediations [88]. Table 2 summarizes the recent works conducted in water and groundwater remediation by nanoremediation technologies.

4.2.3. Metal and Magnetic Nanoparticle

The use of metal and magnetic NPs in water and groundwater remediation has received significant attention due to their unique properties. Ou et al. [90] studied the performance of iron-coated aluminum (Fe/Al) BNPs and aluminum-coated iron (Al/Fe) BNPs for the remediations of Cr(VI) from contaminated groundwater [90]. The results indicated that the Cr(VI) removal rate depended on reactive sites and the saturation concentration when (Fe/Al) was used. Moreover, the results showed that the investigated NPs could decrease Cr(VI) to Cr(III). The removal efficiency was 1.47 g g−1 when (Fe/Al) BNPs were used and 0.07 g g−1 when (Al/Fe) BNPs were used [90]. In a subsequent study, Wang et al. [91] examined the removal of Cr(VI) from contaminated groundwater using iron sulfide NPs (FeS NPs) [91]. The batch test results indicated that a high removal efficiency (1046.1 mg Cr(VI) per gram FeS NPs) was achieved when FeS NPS was used. This high removal efficiency could be attributed to three mechanisms: reduction, adsorption, and co-precipitation. In addition, they found that the pH significantly affected the Cr(VI) removal using FeS NPs. The results suggest that the synthesized Fe NPs could be a promising remediation technology for in situ remediations of Cr(VI) contaminated soil and groundwater [91]. In another study, Xie et al. [92] investigated the immobilization of selenite (Se(IV)) in soil and groundwater using Fe-Me binary oxide NPs [92]. The results showed that high Se(IV) uptake was noticed at a pH range of 5–8, the typical groundwater range. According to Langmuir’s maximum capacity, the adsorption capacity was 109 mg Se(IV) per g Fe-Me NPs [92]. In another study, Dong et al. [93] examined the effect of the aging time of Fe/Ni BNPs on particle activity [93]. Moreover, they investigated the reactivity of aged Fe/Ni BNPs by examining their performance in removing tetracycline (TC). The results showed that the aged time plays a significant role in TC removal. The removal efficiency of TC was in the range of 82.3–92.5%. As the aged time increased to 5–15 days, the removal efficiency of TC decreased by 20–50% to reach around 50%, due to oxidation and aggregation of the particles. Finally, the removal efficiency of TC by 90 days using aged Fe/Ni BNPs was around 30% [93].
Groundwater remediations using MNPs have received attention recently because of their facile separation using a magnet and unique metal-ion adsorption. Many studies recently investigated the performance of MNPs for groundwater restoration. Gong et al. (2017) investigated the performance of FeS-coated iron (Fe/FeS) magnetic NPs (MNPs) for the remediation of Cr(VI)-contaminated groundwater (Figure 3) [80]. The results showed that the molar ratio of S/F has a significant effect on the Fe/FeS MNPs. Increasing the S/Fe molar ratio to 0.138 decreased Cr(VI) removal by 42.8%. However, a further increase of 0.207 increased the removal efficiency by 63% within 72 h.
Moreover, the results indicated that the adsorption process of Cr(VI) by Fe/FeS at S/F molar ration of 0.207 fitted with a pseudo-second-order kinetic model and the sorption capacity was 69.7 mg g−1, which was simulated by the Langmuir isotherm model [80]. Huang and Keller [94] developed a regenerable magnetic ligand nanoparticle (Mag-ligand) to rapidly remove Cd and Pb from contaminated water [94]. The results showed high performance of mega-ligand as Cd and Pb were removed from contaminated water quickly, and Cd was removed in less than 2 h where Pb in less than 15 min. The performance of mega-legend in terms of Cd and Pb was not affected by pH (3–10). In addition, the whole regeneration process can be achieved by washed Mega-legend easily by 1% HCl. The results suggest that modified mega-legend is a feasible nanoparticle for efficient, rapid, and convenient removal of Cd and Pb from the contaminated aquatic system [94]. In a recent study, Alani et al. [96] successfully synthesized zero-valent Cu NPs and examined their performance for dye removal from water [96]. The results showed that the removal time was between 5 and 13 min and over 90% removal efficiency was achieved, indicating that the synthesized zero-valent Cu nanoparticle has a great catalytic ability [96]. In another study, Li et al. [95] examined the performance of magnetic mesoporous silica NPs (MMSNPs) for the remediation of uranium (U(VI)) from high and low pH [95]. The result showed that MMSNPs were efficient for U(VI) removal in the pH range of (3.5–9.6) for artificial groundwater. They found that MMSNPs adsorption capacity can reach 133 g U(VI) per g MMSNPs; these results indicate that MMSNPs are a promising solution for treating U(VI) contaminated groundwater at extreme pH [95]. In a recent study, Ari et al. [97] successfully synthesized α-Fe2O3 NPs via a biosynthesis method using leaf extracts of Azadirachta indica (neem) and a non-toxic precursor salt (FeCl3∙6H2O). In addition, they investigated the potential of using α-Fe2O3 NPs as heterogenous catalyst for tetracycline degradation. The result showed that α-Fe2O3 NPs demonstrated excellent performance as a heterogenous catalyst for degradation of tetracycline aqueous solution by the synergistic effect of the UV/Fenton system [97].

5. Environmental Risk and Ecotoxicology

Although nanomaterials have been used effectively for soil and groundwater remediation, exposure to nanomaterials may have deleterious effects on humans and environments. Toxicological risk assessments need data on both uptake and exposure of nanomaterials and the immediate effects of NPs when they enter the human system. However, to form a conclusion and recommendations, there are limited data in this domain. The process and factors influencing ecotoxicity are complex. Thus, many factors may determine the impact of synthesized NPs on organisms, such as dissolution potential, particle surface properties, aggregation potential, exposure environment properties, and the physiological, biological, and organism behavior when exposed to NPs [14].
Many studies highlighted the impact of nanomaterials on both humans and environments. For example, iron oxide NPs has a mutagenic impact as it may damage organisms’ ability to develop or reproduce [98]. Results indicated exposure to subinhibitory concentrations of amoxicillin-bound iron oxide NPs, in the presence of humic acid, and increased bacterial growth in pseudomonas aeruginosa and Staphylococcus aureus [99]. The joint effects of NPs and other contaminants on terrestrial plants are increasingly investigated but still limited. To provide a sound basis for risk assessment, more research should evaluate the joint effects under realistic conditions [100]. The size and shape of NPs ultimately determine the degree of toxicology. Therefore, not only is monitoring of NPs in soil–plant systems is not essential, but more information is needed on their size allocation and physical properties [101]. Most of the reviewed nano-risk assessment approaches are designed to serve as preliminary risk screening and/or research prioritization tools and are not intended to support regulatory decision making. Although the conventional risk assessment framework is a valuable approach, it may fail to adequately estimate the health and environmental risks from engineering nanomaterials in the near term due to overwhelming methodological limitations and epistemic uncertainties [102]. In this section, an overview of the recent studies about concerns related to the environmental risk of using nanomaterials for soil and groundwater remediation is presented.
Gómez-Sagasti et al. [103] conducted a 3 months experiment to investigate the influence of nZVI concentration (ranging from 1 to 20 mg L−1) on soil microbial properties in two types of soil: sandy-loam and clay-loam soils [103]. The results presented evidence that soil type may affect the degree of potential toxic effects on soil microbial communities by nZVI. The results showed that the accentuated inhibitory impact of nZVI on soil microorganisms in sandy-loam soil was more obvious than clay-loam soil. This can be attributed to the high organic content in clay-loam soil, which acts as a protective agent when nZVI was added to the soil by rendering nZVI inactive, thus prohibiting interaction with soil microorganism cells. Bacterial biomass and arylsulphatase activity, diversity, and richness were negatively influenced by remediation of sandy-loam soil by nZVI. In terms of concentration, they found no obvious concentration–response effect on the soil by nZVI application. The study suggests that many investigations are required using a wide range of soil types and soil proprieties to have clear insight into soil properties’ effect and type on the impact of nZVI on soil bacteria communities [103]. In another study, Dong et al. [104] investigated the effects of carboxymethyl cellulose (CMC) surface coating on the cytotoxicity and colloidal stability of nZVI towards Escherichia coli (E. coli) and studied the interrelation between cytotoxicity and particle stability [104]. In addition, they examined the influence of CMC ionic strength (Ca2+), concentration, and aging treatment on particle cytotoxicity. The results indicated that nZVI without coating harms E. coli and time- and concentration-dependent.
On the other hand, the cytotoxicity of nZVI decreased when the nZVI particles were coated with CMC. This can be attributed to the cell membrane that kept intact in CMC- modified nZVI, whereas cell membrane disruption could be observed when bare nZVI contact with E. coli. The aged nZVI and CMC-nZVI did not affect E. coli due to the Fe0 transformation to less toxic iron oxide. The toxicity of nZVI and CMC-nZVI related to the existence of Ca2+ was concentration-dependent as it can either decrease or increase. The presence of Ca2+ could decrease the toxicity of nZVI by causing aggregation and settling of nZVI.
However, the presence of Ca2+ could also increase the toxicity of nZVI by facilitating the adhesion of NPs onto the bacteria surface, forming a more toxic effect [104]. In another study, Chaithawiwat et al. [105] studied the effect of nZVI on the bacterial growth phases on four bacterial strains [105]. The results showed that lag and stationary phases for all bacterial strains were resistant to nZVI, whereas the bacterial strains in exponential and decline phases showed less resistance than lag and stationary phrases. In addition, the results indicated that increasing the nZVI concentration increased bacterial inactivation. The results suggest that it is necessary to consider the bacterial growth phase and nZVI concentration when studying the influence of nZVI on the bacteria [105]. In a subsequent study, Cheng et al. [106] examine the toxicity of S-nZVI to E. coli in an aqueous solution [106]. The result indicated that the toxicity of nZVI could be reduced by sulfidation as S/nZVI showed less toxicity at a lower F/S molar ratio, coming out from the higher iron oxide and sulfate and lower Fe0 content. The results suggest that the typical groundwater contents (i.e., Ca2+, HCO3−, SO42−, and humic acid) could drop the toxicity of nZVI. In addition, in the presence of groundwater mix components, the S/nZVI toxicity was negligible. The results suggest that the implication of S/nZVI could present a low toxicity risk in the ecosystem [106]. In a recent study, Li et al. [107] conducted a long-term study to examine the effect of zeolite-supported nZVI (Z-nZVI) on farmland soils on bacterial communities during the remediation of metals (Cd, As, Pb) [107]. The result indicated that temporary shifts in pH-sensitive, iron resistance/sensitivity, metal resistance, and denitrifying bacteria after adding Z-nZVI were eliminated due to the soil characteristics that drove the re-establishment of the indigenous bacterial community Z-nZVI and restored the bacterial DNA replication and denitrification activity in the soil. The results suggest that Z-nZVI is a promising nanoremediation technology for long-term metal-contaminated soil remediation without ecotoxicity effects [107].
The toxicity of using CNTs in soil and groundwater remediation has been studied by many researchers [108]. However, there are insufficient data related to the effect of CNTs on both humans and the environment. Song et al. [109] studied the effects of MWCNTs different dosages (0.5, 1.0, 2.0, wt%) on bacterial communities, especially the metabolic function, in phenanthrene contaminated sediment [109]. The results indicated that the metabolic function of microbial communities could be significantly changed by the application of high dosage (0.5–2.0, wt%). This can be attributed to the utilization of carbon sources on Biolog ECO microplate. Remotion of phenanthrene-contaminated sediment with 0.5% MWCNTs presented the best microbial activity and Shannon–Wiener diversity index [109].

6. Combined Nanoremediation with Other Remediation Technology

The combination of nanoremediation technologies with other mitigation methods has attracted significant research in recent years. Synergetic studies can be characterized as combining multiple nanoremediation methods simultaneously or combined with soil flushing or with biotreatment. In this section, an overview of the recent work in this domain is presented.
Several studies combined many nanoremediation methods at the same time. Vilardi et al. [110] examined the combination of nZVI and CNTs for the remediation of Cr(VI), selenium (Se), and cobalt (Co) from aqueous solutions by conducted a batch experiment [110]. The result indicated that for Cr(VI), the main removal mechanism the reduction, whereas adsorption was the predominant mechanism for other metals. The results showed that the Cr(VI) removal efficiency was 100% when nZVI was used alone without pH change, whereas it decreased to around 90% when CNTs-nZVI nanocomposite was used. On the other hand, using CNTs-nZVI showed high removal efficiency for Se and Co at 90% and 80%, respectively. The results suggest that the CNTs–nZVI nanocomposite showed high adsorption efficiency for remediation of heavy metals-contaminated water [110]. In another study, Zhang et al. [111] studied the performance of carboxymethyl cellulose (CMC)-stabilized nZVI composited with BC (CMC-nZVI/BC) for remediation of Cr(VI)-contaminated soil [111]. The results indicated that, after 21 days, the immobilization efficiency of Cr(VI) was 19.7, 33.3, and 100% when the dosage of CMC-nZVI/BC was 11, 27.5, and 55 g Kg−1, respectively. The results suggest that the addition of BC to CMC-nZVI could decrease the Cr(VI) transformation slightly, as a small part of CMC-nZVI could be adsorbed to biochar. The Crtotal removal efficiency was high because the reduction reaction continued to remediation [69]. In a recent study, Qian et al. [112], for the first time, investigated the performance of biochar-nZVI for the remediation of chlorinated hydrocarbon in the field [112]. They used direct-push and water pressure-driven packer techniques. The field study results demonstrated a sharp reduction of chlorinated solvents in the 24 h after the first injection of nZVI, but within the next two weeks, a rebound of the concentrations in groundwater was observed. However, the implementation of biochar-nZVI highly improved the removal of the chlorinated solvent from groundwater for 42 days (Figure 4). The results suggest that biochar-nZVI is a promising combined technology for chlorinated solvent contaminated groundwater remediation [112].
Galdames et al. [29] developed a new approach combining nanoremediation with bioremediation for hydrocarbon and heavy metals remediation from contaminated soil [29]. Specifically, the method uses a combination of nZVI and compost from organic waste. The results indicated that the combination of nZVI and compost could decrease the aliphatic hydrocarbons concentration up to 60% even under uncontrolled conditions. In addition, they observed a remarkable decrease in ecotoxicity in the bio-pile of soil [29]. In another study, Alabresm et al. [113] studied the combination of PVP-coated magnetite NPs with oil-degrading bacteria for crude oil remediation at the lab scale [113]. The result indicated that NPs alone removed around 70% of high oil concentration after 1 h. However, the removal efficiency did not increase due to the saturation of NPs. On the other hand, bioremediation by oil-degrading bacteria removed 90% of oil after 48 h. Finally, the combination of NPs and oil-degrading bacteria could completely remove the oil within 48 h. This was attributed to the sorption of oil components to NPs and following degradation by bacteria. Further investigation is needed to understand the oil removal mechanism when combining NPs with oil-degrading bacteria are used for oil remediation [113].
Recently, Czinnerova et al. [114] conducted a long-term field study that investigated the degradation of chlorinated ethenes (CEs) by using nZVI supported by electrokinetic (EK) treatment (nZVI-EK) [114]. EK may enhance the nZVI impact on soil bacteria and increased the migration and longevity of nZVI. The results indicated a rapid decrease in cis-1,2-dichloroethene (cDCE) at around 70%, followed by setting new geochemical conditions as a degradation product of CE (ethene, ethane, and methane) was observed. These new conditions enhanced the growth of soil and ground bacteria, such as organohalide-respiring bacteria. The results suggest that nZVI-EK remediation technology is a promising method for CE remediation from soil and groundwater and enhanced bacteria availability in soil and groundwater [114]. In another study, Sierra et al. [115] studied a combination of soil washing and nZVI for the removal and recovery of toxic elements (As, Cu, Hg, Pb, Sb) from polluted soil (Figure 5) [115]. The results showed that a high recovery yield was obtained for Pb, Cu, and Sb in the magnetically separated fraction, whereas Hg was concentrated in a non-magnetic fraction. Taking everything into account, the soil washing efficiency was enhanced by adding nZVI, especially for a larger fraction. The results suggest that the investigated methodology opens the door for NPs’ use in soil-washing remediation [115].
Qu et al. [116] studied the implication of an activated carbon fiber (ACF)-supported nZVI (ACF-nZVI) composite for Cr(VI) remediation from groundwater [116]. In addition, they examined the effect of the operation condition such as nZVI amount on activated carbon fiber, initial Cr(VI) concentration, and pH value on the Cr(VI) removal by conducting a batch experiment. The results indicated that the aggregation of nZVI could be inhabited by ACF, which increases the nZVI reactivity and Cr(VI) removal efficiency. The removal efficiency of Cr(VI) decreased with increasing Cr(VI) initial concentration, whereas, in an acidic environment, complete removal (100%) of Cr(VI) was observed in 1 h reaction time. The proposed removal mechanism consisted of two steps: the first step was the physical adsorption of Cr(VI) on the ACF-nZVI surface area or inner layer, where the second step was a reduction of Cr(VI) to Cr(III) by nZVI [116]. In another study, Huang et al. [117] studied the activation of persulfate (PS) by using a zeolite-supported nZVI composites (PS-Z/nZVI) system and examined its efficiency for TCE degradation. The results indicated that Z/nZVI showed high ability towards PS activation (1.5 mM), and high removal efficiency (98.8%) of TCE was observed at pH 7 within 2 h. Moreover, the PS-Z/nZVI system showed high efficiency in terms of TCE for a wide range of pH (4–7) [117]. Table 3 summarizes the recent works conducted in soil and groundwater remediation by combining nanoremediation technologies with other remediation methods.

7. Conclusions

This review aims to present the latest advances in nanoremediation of contaminated soil and groundwater. The main advantages of using nanomaterials in soil remediation are reduction in cleanup time and overall costs, decreased pollutants to nearly zero in the site, and no need to dispose of polluted soil. The wide use of nZVI nanomaterials in environmental cleanup is due to their high reactivity and high ability to immobilize heavy metals such as Cd, Ni, and Pb. Modifying and/or coating nZVI may decrease the toxicity effects on soil microorganisms. The high adsorption capacity of CNTs is from the large surface area, which makes CNTs a great nanomaterial for organic and inorganic remediation. More studies are needed to investigate the effect of CNTs on the environment.
Soil and groundwater remediation using metal and MNPs is a promising technology due to the unique separation mechanism. Full-scale application of nanoremediation needs further evaluation, particularly in terms of efficiency and potential adverse environmental impacts. Combining nanoremediation with other remediation technology appears to be the future of soil remediation as the combination process increases the sustainable remediation practice towards green environmental protection practice.

8. Recommendation and Future Prospective

This review provides readers with a general overview of using nanoremediation for environmental cleanups, particularly soil and groundwater remediation. More work is needed to developing smarter nanomaterials for soil remediation. For instance, more advanced development could produce NPs with a high ability to work with several functions, such as interacting with hydrophilic and hydrophobic materials or catalyzing many pollutant reactions on the same particle. In addition, further research is needed to design and synthesize NPs that can remediate a wide range of contaminants; and enhance the injecting systems.
Most existing research on nanoremediation is confined to laboratory studies and modeling. Transferring these studies to in situ conditions is a challenge. Thus, more investigations are required in order to develop standard protocols and doses for the application of nanomaterials at the field level. Moreover, efforts should also focus on the application of nanoremediation in the field to understand nanoparticle’s fate and transport behavior in soil, water, and sediments and how they affect the environmental variables.
Nanoremediation has been developed and evaluated over the last 20 years. There is, however, concern about its effects on both humans and the environment. With the rapid advancement of nanoremediation techniques, proper evaluation needs to be done to prevent or mitigate any potential environmental or ecological hazards.
In addition, the need for a more thorough understanding of the contaminants’ removal processes and the nanomaterials behavior in nature has led to experimentation where no contaminant is present. Many researchers have examined the impacts of nanoremediation on the soil and groundwater bacteria, yet a clear insight into the interaction between nanoremediation materials such as nZVI and microbial activity is still unclear.

Author Contributions

Conceptualization and Funding, M.Y.D.A.; Writing—Original Draft Preparation, A.A. and M.Y.D.A.; Writing—Review and Editing, G.A.M.A.; N.K.C.; S.S.A.A.; M.F.M.A.; and T.A.M.; Validation, M.J.K.B. All authors have read and agreed to the published version of the manuscript.

Funding

The research leading to these results has received funding from Ministry of Higher Education, Research, and Innovation (MoHERI) of the Sultanate of Oman under the Block Funding Program, MoHERI Block Funding Agreement No. MoHERI/BFP/ASU/01/2020.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data is contained within the article.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Cheng, M.; Zeng, G.; Huang, D.; Lai, C.; Xu, P.; Zhang, C.; Liu, Y. Hydroxyl radicals based advanced oxidation processes (AOPs) for remediation of soils contaminated with organic compounds: A review. Chem. Eng. J. 2016, 284, 582–598. [Google Scholar] [CrossRef]
  2. Thomé, A.; Reddy, K.R.; Reginatto, C.; Cecchin, I. Review of Nanotechnology for Soil and Groundwater Remediation: Brazilian Perspectives. Water Air Soil Pollut. 2015, 226, 121. [Google Scholar] [CrossRef]
  3. Mateas, D.J.; Tick, G.R.; Carroll, K.C. In situ stabilization of NAPL contaminant source-zones as a remediation technique to reduce mass discharge and flux to groundwater. J. Contam. Hydrol. 2017, 204, 40–56. [Google Scholar] [CrossRef]
  4. Rajan, C.S.R. Nanotechnology in Groundwater Remediation. Int. J. Environ. Sci. Dev. 2011, 2, 182–187. [Google Scholar] [CrossRef]
  5. Tsai, T.T.; Kao, C.M.; Yeh, T.Y.; Lee, M.S. Chemical Oxidation of Chlorinated Solvents in Contaminated Groundwater: Review. Pract. Period. Hazard. Toxic Radioact. Waste Manag. 2008, 12, 116–126. [Google Scholar] [CrossRef]
  6. Honetschlägerová, L.; Martinec, M.; Škarohlíd, R. Coupling in situ chemical oxidation with bioremediation of chloroethenes: A review. Rev. Environ. Sci. Bio/Technol. 2019, 18, 699–714. [Google Scholar] [CrossRef]
  7. Chaney, R.L.; Reeves, P.G.; Ryan, J.A.; Simmons, R.W.; Welch, R.M.; Scott Angle, J. An improved understanding of soil Cd risk to humans and low cost methods to phytoextract Cd from contaminated soils to prevent soil Cd risks. Biometals 2004, 17, 549–553. [Google Scholar] [CrossRef]
  8. Liu, J.-W.; Wei, K.-H.; Xu, S.-W.; Cui, J.; Ma, J.; Xiao, X.-L.; Xi, B.-D.; He, X.-S. Surfactant-enhanced remediation of oil-contaminated soil and groundwater: A review. Sci. Total Environ. 2021, 756, 144142. [Google Scholar] [CrossRef]
  9. Yang, C.; Offiong, N.-A.; Zhang, C.; Liu, F.; Dong, J. Mechanisms of irreversible density modification using colloidal biliquid aphron for dense nonaqueous phase liquids in contaminated aquifer remediation. J. Hazard. Mater. 2021, 415, 125667. [Google Scholar] [CrossRef] [PubMed]
  10. Gupta, V.K.; Agarwal, S.; Sadegh, H.; Ali, G.A.M.; Bharti, A.K.; Hamdy, A.S. Facile route synthesis of novel graphene oxide-β-cyclodextrin nanocomposite and its application as adsorbent for removal of toxic bisphenol A from the aqueous phase. J. Mol. Liq. 2017, 237, 466–472. [Google Scholar] [CrossRef] [Green Version]
  11. Sadegh, H.; Ali, G.A.M.; Makhlouf, A.S.H.; Chong, K.F.; Alharbi, N.S.; Agarwal, S.; Gupta, V.K. MWCNTs-Fe3O4 nanocomposite for Hg(II) high adsorption efficiency. J. Mol. Liq. 2018, 258, 345–353. [Google Scholar] [CrossRef]
  12. Lee, S.P.; Ali, G.A.M.; Algarni, H.; Chong, K.F. Flake size-dependent adsorption of graphene oxide aerogel. J. Mol. Liq. 2019, 277, 175–180. [Google Scholar] [CrossRef]
  13. Arabi, S.M.S.; Lalehloo, R.S.; Olyai, M.R.T.B.; Ali, G.A.M.; Sadegh, H. Removal of congo red azo dye from aqueous solution by ZnO nanoparticles loaded on multiwall carbon nanotubes. Phys. E Low-Dimens. Syst. Nanostruct. 2019, 106, 150–155. [Google Scholar] [CrossRef]
  14. Karn, B.; Kuiken, T.; Otto, M. Nanotechnology and in Situ Remediation: A Review of the Benefits and Potential Risks. Environ. Health Perspect. 2009, 117, 1813–1831. [Google Scholar] [CrossRef] [Green Version]
  15. Ganie, A.S.; Bano, S.; Khan, N.; Sultana, S.; Rehman, Z.; Rahman, M.M.; Sabir, S.; Coulon, F.; Khan, M.Z. Nanoremediation technologies for sustainable remediation of contaminated environments: Recent advances and challenges. Chemosphere 2021, 275, 130065. [Google Scholar] [CrossRef]
  16. Akharame, M.O.; Fatoki, O.S.; Opeolu, B.O. Regeneration and Reuse of Polymeric Nanocomposites in Wastewater Remediation: The Future of Economic Water Management; Springer: Berlin/Heidelberg, Germany, 2019; Volume 76, pp. 647–681. [Google Scholar]
  17. Chaturvedi, S.; Dave, P.N. Water purification using nanotechnology an emerging opportunities. Chem. Methodol. 2019, 3, 115–144. [Google Scholar]
  18. Kumar, A.; Joshi, H.; Kumar, A. Remediation of Arsenic by Metal/Metal Oxide Based Nanocomposites/Nanohybrids: Contamination Scenario in Groundwater, Practical Challenges, and Future Perspectives. Sep. Purif. Rev. 2020, 50, 283–314. [Google Scholar] [CrossRef]
  19. Blundell, S.P.; Owens, G. Evaluation of enhancement techniques for the dechlorination of DDT by nanoscale zero-valent iron. Chemosphere 2021, 264, 128324. [Google Scholar] [CrossRef] [PubMed]
  20. Chen, J.; Dong, H.; Tian, R.; Li, R.; Xie, Q. Remediation of Trichloroethylene-Contaminated Groundwater by Sulfide-Modified Nanoscale Zero-Valent Iron Supported on Biochar: Investigation of Critical Factors. Water Air Soil Pollut. 2020, 231, 432. [Google Scholar] [CrossRef]
  21. Gil-Díaz, M.; Álvarez, M.A.; Alonso, J.; Lobo, M.C. Effectiveness of nanoscale zero-valent iron for the immobilization of Cu and/or Ni in water and soil samples. Sci. Rep. 2020, 10, 15927. [Google Scholar] [CrossRef]
  22. Mpouras, T.; Polydera, A.; Dermatas, D.; Verdone, N.; Vilardi, G. Multi wall carbon nanotubes application for treatment of Cr(VI)-contaminated groundwater; Modeling of batch & column experiments. Chemosphere 2021, 269, 128749. [Google Scholar]
  23. 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. [Google Scholar] [CrossRef]
  24. Araújo, R.; Castro, A.C.M.; Fiúza, A. The Use of Nanoparticles in Soil and Water Remediation Processes. Mater. Today Proc. 2015, 2, 315–320. [Google Scholar] [CrossRef]
  25. Mukhopadhyay, R.; Sarkar, B.; Khan, E.; Alessi, D.S.; Biswas, J.K.; Manjaiah, K.M.; Eguchi, M.; Wu, K.C.W.; Yamauchi, Y.; Ok, Y.S. Nanomaterials for sustainable remediation of chemical contaminants in water and soil. Crit. Rev. Environ. Sci. Technol. 2021, 1–50. [Google Scholar] [CrossRef]
  26. Savolainen, K.; Alenius, H.; Norppa, H.; Pylkkänen, L.; Tuomi, T.; Kasper, G. Risk assessment of engineered nanomaterials and nanotechnologies—A review. Toxicology 2010, 269, 92–104. [Google Scholar] [CrossRef]
  27. Patil, S.S.; Shedbalkar, U.U.; Truskewycz, A.; Chopade, B.A.; Ball, A.S. Nanoparticles for environmental clean-up: A review of potential risks and emerging solutions. Environ. Technol. Innov. 2016, 5, 10–21. [Google Scholar] [CrossRef]
  28. Pak, T.; de Lima Luz, L.F.; Tosco, T.; Costa, G.S.R.; Rosa, P.R.R.; Archilha, N.L. Pore-scale investigation of the use of reactive nanoparticles for in situ remediation of contaminated groundwater source. Proc. Natl. Acad. Sci. USA 2020, 117, 13366–13373. [Google Scholar] [CrossRef] [PubMed]
  29. Galdames, A.; Mendoza, A.; Orueta, M.; de Soto García, I.S.; Sánchez, M.; Virto, I.; Vilas, J.L. Development of new remediation technologies for contaminated soils based on the application of zero-valent iron nanoparticles and bioremediation with compost. Resour. Effic. Technol. 2017, 3, 166–176. [Google Scholar] [CrossRef]
  30. Thavamani, P.; Smith, E.; Kavitha, R.; Mathieson, G.; Megharaj, M.; Srivastava, P.; Naidu, R. Risk based land management requires focus beyond the target contaminants—A case study involving weathered hydrocarbon contaminated soils. Environ. Technol. Innov. 2015, 4, 98–109. [Google Scholar] [CrossRef]
  31. Anyika, C.; Abdul Majid, Z.; Ibrahim, Z.; Zakaria, M.P.; Yahya, A. The impact of biochars on sorption and biodegradation of polycyclic aromatic hydrocarbons in soils—A review. Environ. Sci. Pollut. Res. 2015, 22, 3314–3341. [Google Scholar] [CrossRef]
  32. Shayegan, H.; Ali, G.A.M.; Safarifard, V. Recent Progress in the Removal of Heavy Metal Ions from Water Using Metal-Organic Frameworks. ChemistrySelect 2020, 5, 124–146. [Google Scholar] [CrossRef] [Green Version]
  33. Moreno-Sader, K.; García-Padilla, A.; Realpe, A.; Acevedo-Morantes, M.; Soares, J.B.P. Removal of Heavy Metal Water Pollutants (Co2+ and Ni2+) Using Polyacrylamide/Sodium Montmorillonite (PAM/Na-MMT) Nanocomposites. ACS Omega 2019, 4, 10834–10844. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  34. Cameselle, C.; Chirakkara, R.A.; Reddy, K.R. Electrokinetic-enhanced phytoremediation of soils: Status and opportunities. Chemosphere 2013, 93, 626–636. [Google Scholar] [CrossRef]
  35. Rodrigo, M.A.; Oturan, N.; Oturan, M.A. Electrochemically Assisted Remediation of Pesticides in Soils and Water: A Review. Chem. Rev. 2014, 114, 8720–8745. [Google Scholar] [CrossRef] [PubMed]
  36. Chang, K.-S.; Lo, W.-H.; Lin, W.-M.; Wen, J.-X.; Yang, S.-C.; Huang, C.-J.; Hsieh, H.-Y. Microwave-Assisted Thermal Remediation of Diesel Contaminated Soil. Eng. J. 2016, 20, 93–100. [Google Scholar] [CrossRef] [Green Version]
  37. Camenzuli, D.; Freidman, B.L.; Statham, T.M.; Mumford, K.A.; Gore, D.B. On-site and in situ remediation technologies applicable to metal-contaminated sites in Antarctica and the Arctic: A review. Polar Res. 2013, 32, 21522. [Google Scholar] [CrossRef]
  38. Ossai, I.C.; Ahmed, A.; Hassan, A.; Hamid, F.S. Remediation of soil and water contaminated with petroleum hydrocarbon: A review. Environ. Technol. Innov. 2020, 17, 100526. [Google Scholar] [CrossRef]
  39. Guerra, F.; Attia, M.; Whitehead, D.; Alexis, F. Nanotechnology for Environmental Remediation: Materials and Applications. Molecules 2018, 23, 1760. [Google Scholar] [CrossRef] [Green Version]
  40. Huang, D.; Qin, X.; Peng, Z.; Liu, Y.; Gong, X.; Zeng, G.; Huang, C.; Cheng, M.; Xue, W.; Wang, X.; et al. Nanoscale zero-valent iron assisted phytoremediation of Pb in sediment: Impacts on metal accumulation and antioxidative system of Lolium perenne. Ecotoxicol. Environ. Saf. 2018, 153, 229–237. [Google Scholar] [CrossRef] [PubMed]
  41. Peluffo, M.; Rosso, J.A.; Morelli, I.S.; Mora, V.C. Strategies for oxidation of PAHs in aged contaminated soil by batch reactors. Ecotoxicol. Environ. Saf. 2018, 151, 76–82. [Google Scholar] [CrossRef] [PubMed]
  42. Fouad, O.A.; Makhlouf, S.A.; Ali, G.A.M.; El-Sayed, A.Y. Cobalt/silica nanocomposite via thermal calcination-reduction of gel precursors. Mater. Chem. Phys. 2011, 128, 70–76. [Google Scholar] [CrossRef]
  43. Fouad, O.A.; Ali, G.A.M.; El-Erian, M.A.I.; Makhlouf, S.A. Humidity sensing properties of cobalt oxide/silica nanocomposites prepared via sol-gel and related routes. Nano 2012, 7, 1250038. [Google Scholar] [CrossRef]
  44. Ali, G.A.M.; Fouad, O.A.; Makhlouf, S.A. Structural, optical and electrical properties of sol-gel prepared mesoporous Co3O4/SiO2 nanocomposites. J. Alloys Compd. 2013, 579, 606–611. [Google Scholar] [CrossRef] [Green Version]
  45. Ali, G.A.M.; Fouad, O.A.; Makhlouf, S.A.; Yusoff, M.M.; Chong, K.F. Co3O4/SiO2 nanocomposites for supercapacitor application. J. Solid State Electrochem. 2014, 18, 2505–2512. [Google Scholar] [CrossRef] [Green Version]
  46. Sadegh, H.; Ali, G.A.M.; Gupta, V.K.; Makhlouf, A.S.H.; Shahryari-ghoshekandi, R.; Nadagouda, M.N.; Sillanpää, M.; Megiel, E. The role of nanomaterials as effective adsorbents and their applications in wastewater treatment. J. Nanostruct. Chem. 2017, 7, 1–14. [Google Scholar] [CrossRef] [Green Version]
  47. Abdel Ghafar, H.H.; Ali, G.A.M.; Fouad, O.A.; Makhlouf, S.A. Enhancement of adsorption efficiency of methylene blue on Co3O4/SiO2 nanocomposite. Desalin. Water Treat. 2015, 53, 2980–2989. [Google Scholar] [CrossRef] [Green Version]
  48. Otto, M.; Floyd, M.; Bajpai, S. Nanotechnology for site remediation. Remediat. J. 2008, 19, 99–108. [Google Scholar] [CrossRef]
  49. Shayegan, H.; Ali, G.A.M.; Safarifard, V. Amide-Functionalized Metal–Organic Framework for High Efficiency and Fast Removal of Pb(II) from Aqueous Solution. J. Inorg. Organomet. Polym. Mater. 2020, 30, 3170–3178. [Google Scholar] [CrossRef]
  50. Ali, G.A.M.; Makhlouf, A.S.H. Fundamentals of Waste Recycling for Nanomaterial Manufacturing. In Waste Recycling Technologies for Nanomaterials Manufacturing; Makhlouf, A.S.H., Ali, G.A.M., Eds.; Springer International Publishing: Cham, Switzerland, 2021; pp. 3–24. [Google Scholar] [CrossRef]
  51. Niemeyer, C.M. Nanoparticles, Proteins, and Nucleic Acids: Biotechnology Meets Materials Science. Angew. Chem. Int. Ed. 2001, 40, 4128–4158. [Google Scholar] [CrossRef]
  52. Ma, C.; Liu, F.-Y.; Wei, M.-B.; Zhao, J.-H.; Zhang, H.-Z. Synthesis of Novel Core-Shell Magnetic Fe3O4@C Nanoparticles with Carboxyl Function for Use as an Immobilisation Agent to Remediate Lead-Contaminated Soils. Pol. J. Environ. Stud. 2020, 29, 2273–2283. [Google Scholar] [CrossRef]
  53. Meteku, B.E.; Huang, J.; Zeng, J.; Subhan, F.; Feng, F.; Zhang, Y.; Qiu, Z.; Aslam, S.; Li, G.; Yan, Z. Magnetic metal–organic framework composites for environmental monitoring and remediation. Coord. Chem. Rev. 2020, 413, 213261. [Google Scholar] [CrossRef]
  54. Nematollahzadeh, A.; Seraj, S.; Mirzayi, B. Catecholamine coated maghemite nanoparticles for the environmental remediation: Hexavalent chromium ions removal. Chem. Eng. J. 2015, 277, 21–29. [Google Scholar] [CrossRef]
  55. Zeng, H.; Zhai, L.; Qiao, T.; Yu, Y.; Zhang, J.; Li, D. Efficient removal of As(V) from aqueous media by magnetic nanoparticles prepared with Iron-containing water treatment residuals. Sci. Rep. 2020, 10, 9335. [Google Scholar] [CrossRef]
  56. Zhu, S.; Wu, Y.; Qu, Z.; Zhang, L.; Yu, Y.; Xie, X.; Huo, M.; Yang, J.; Bian, D.; Zhang, H.; et al. Green synthesis of magnetic sodalite sphere by using groundwater treatment sludge for tetracycline adsorption. J. Clean. Prod. 2020, 247, 119140. [Google Scholar] [CrossRef]
  57. Giahi, M.; Pathania, D.; Agarwal, S.; Ali, G.A.M.; Chong, K.F.; Gupta, V.K. Preparation of Mg-doped TiO2 nanoparticles for photocatalytic degradation of some organic pollutants. Stud. Univ. Babes Bolyai Chem. 2019, 64, 7–18. [Google Scholar] [CrossRef]
  58. Li, Q.; Chen, X.; Zhuang, J.; Chen, X. Decontaminating soil organic pollutants with manufactured nanoparticles. Environ. Sci. Pollut. Res. 2016, 23, 11533–11548. [Google Scholar] [CrossRef] [PubMed]
  59. Yaqoob, A.A.; Parveen, T.; Umar, K.; Mohamad Ibrahim, M.N. Role of Nanomaterials in the Treatment of Wastewater: A Review. Water 2020, 12, 495. [Google Scholar] [CrossRef] [Green Version]
  60. Baby, R.; Saifullah, B.; Hussein, M.Z. Carbon Nanomaterials for the Treatment of Heavy Metal-Contaminated Water and Environmental Remediation. Nanoscale Res. Lett. 2019, 14, 341. [Google Scholar] [CrossRef] [Green Version]
  61. Benamar, A.; Mahjoubi, F.Z.; Ali, G.A.M.; Kzaiber, F.; Oussama, A. A chemometric method for contamination sources identification along the Oum Er Rbia river (Morocco). Bulg. Chem. Commun. 2020, 52, 159–171. [Google Scholar]
  62. Zhang, W.-X. Nanoscale Iron Particles for Environmental Remediation: An Overview. J. Nanopart. Res. 2003, 5, 323–332. [Google Scholar] [CrossRef]
  63. Mondal, A.; Dubey, B.K.; Arora, M.; Mumford, K. Porous media transport of iron nanoparticles for site remediation application: A review of lab scale column study, transport modelling and field-scale application. J. Hazard. Mater. 2021, 403, 123443. [Google Scholar] [CrossRef]
  64. Tian, H.; Liang, Y.; Yang, D.; Sun, Y. Characteristics of PVP–stabilised NZVI and application to dechlorination of soil–sorbed TCE with ionic surfactant. Chemosphere 2020, 239, 124807. [Google Scholar] [CrossRef]
  65. Reginatto, C.; Cecchin, I.; Heineck, K.S.; Thomé, A.; Reddy, K.R. Use of Nanoscale Zero-Valent Iron for Remediation of Clayey Soil Contaminated with Hexavalent Chromium: Batch and Column Tests. Int. J. Environ. Res. Public Health 2020, 17, 1001. [Google Scholar] [CrossRef] [Green Version]
  66. Shubair, T.; Eljamal, O.; Khalil, A.M.E.; Matsunaga, N. Multilayer system of nanoscale zero valent iron and Nano-Fe/Cu particles for nitrate removal in porous media. Sep. Purif. Technol. 2018, 193, 242–254. [Google Scholar] [CrossRef]
  67. Xue, W.; Huang, D.; Zeng, G.; Wan, J.; Zhang, C.; Xu, R.; Cheng, M.; Deng, R. Nanoscale zero-valent iron coated with rhamnolipid as an effective stabilizer for immobilization of Cd and Pb in river sediments. J. Hazard. Mater. 2018, 341, 381–389. [Google Scholar] [CrossRef] [PubMed]
  68. Apul, O.G.; Delgado, A.G.; Kidd, J.; Alam, F.; Dahlen, P.; Westerhoff, P. Carbonaceous nano-additives augment microwave-enabled thermal remediation of soils containing petroleum hydrocarbons. Environ. Sci. Nano 2016, 3, 997–1002. [Google Scholar] [CrossRef]
  69. Zhang, Y.; Yang, J.; Zhong, L.; Liu, L. Effect of multi-wall carbon nanotubes on Cr(VI) reduction by citric acid: Implications for their use in soil remediation. Environ. Sci. Pollut. Res. 2018, 25, 23791–23798. [Google Scholar] [CrossRef]
  70. Cheng, J.; Sun, Z.; Yu, Y.; Li, X.; Li, T. Effects of modified carbon black nanoparticles on plant-microbe remediation of petroleum and heavy metal co-contaminated soils. Int. J. Phytoremediat. 2019, 21, 634–642. [Google Scholar] [CrossRef] [PubMed]
  71. Zhang, J.; Gong, J.-L.; Zeng, G.-M.; Yang, H.-C.; Zhang, P. Carbon nanotube amendment for treating dichlorodiphenyltrichloroethane and hexachlorocyclohexane remaining in Dong-ting Lake sediment—An implication for in-situ remediation. Sci. Total Environ. 2017, 579, 283–291. [Google Scholar] [CrossRef]
  72. Abbasian, F.; Lockington, R.; Palanisami, T.; Megharaj, M.; Naidu, R. Multiwall carbon nanotubes increase the microbial community in crude oil contaminated fresh water sediments. Sci. Total Environ. 2016, 539, 370–380. [Google Scholar] [CrossRef]
  73. Hua, S.; Gong, J.-L.; Zeng, G.-M.; Yao, F.-B.; Guo, M.; Ou, X.-M. Remediation of organochlorine pesticides contaminated lake sediment using activated carbon and carbon nanotubes. Chemosphere 2017, 177, 65–76. [Google Scholar] [CrossRef]
  74. Naderi Peikam, E.; Jalali, M. Application of three nanoparticles (Al2O3, SiO2 and TiO2) for metal-contaminated soil remediation (measuring and modeling). Int. J. Environ. Sci. Technol. 2018, 16, 7207–7220. [Google Scholar] [CrossRef]
  75. Qiao, Y.; Wu, J.; Xu, Y.; Fang, Z.; Zheng, L.; Cheng, W.; Tsang, E.P.; Fang, J.; Zhao, D. Remediation of cadmium in soil by biochar-supported iron phosphate nanoparticles. Ecol. Eng. 2017, 106, 515–522. [Google Scholar] [CrossRef]
  76. Baragaño, D.; Alonso, J.; Gallego, J.R.; Lobo, M.C.; Gil-Díaz, M. Zero valent iron and goethite nanoparticles as new promising remediation techniques for As-polluted soils. Chemosphere 2020, 238, 124624. [Google Scholar] [CrossRef]
  77. Fan, L.; Song, J.; Bai, W.; Wang, S.; Zeng, M.; Li, X.; Zhou, Y.; Li, H.; Lu, H. Chelating capture and magnetic removal of non-magnetic heavy metal substances from soil. Sci. Rep. 2016, 6, 21027. [Google Scholar] [CrossRef]
  78. Baragaño, D.; Alonso, J.; Gallego, J.R.; Lobo, M.C.; Gil-Díaz, M. Magnetite nanoparticles for the remediation of soils co-contaminated with As and PAHs. Chem. Eng. J. 2020, 399, 125809. [Google Scholar] [CrossRef]
  79. Savage, N.; Diallo, M.S. Nanomaterials and Water Purification: Opportunities and Challenges. J. Nanopart. Res. 2005, 7, 331–342. [Google Scholar] [CrossRef]
  80. Gong, Y.; Gai, L.; Tang, J.; Fu, J.; Wang, Q.; Zeng, E.Y. Reduction of Cr(VI) in simulated groundwater by FeS-coated iron magnetic nanoparticles. Sci. Total Environ. 2017, 595, 743–751. [Google Scholar] [CrossRef]
  81. Gillham, R.W.; O’Hannesin, S.F. Enhanced Degradation of Halogenated Aliphatics by Zero-Valent Iron. Groundwater 1994, 32, 958–967. [Google Scholar] [CrossRef]
  82. Wang, C.-B.; Zhang, W.-X. Synthesizing Nanoscale Iron Particles for Rapid and Complete Dechlorination of TCE and PCBs. Environ. Sci. Technol. 1997, 31, 2154–2156. [Google Scholar] [CrossRef]
  83. Tosco, T.; Petrangeli Papini, M.; Cruz Viggi, C.; Sethi, R. Nanoscale zerovalent iron particles for groundwater remediation: A review. J. Clean. Prod. 2014, 77, 10–21. [Google Scholar] [CrossRef]
  84. Lin, K.-S.; Mdlovu, N.V.; Chen, C.-Y.; Chiang, C.-L.; Dehvari, K. Degradation of TCE, PCE, and 1,2–DCE DNAPLs in contaminated groundwater using polyethylenimine-modified zero-valent iron nanoparticles. J. Clean. Prod. 2018, 175, 456–466. [Google Scholar] [CrossRef]
  85. Dong, H.; Zhang, C.; Deng, J.; Jiang, Z.; Zhang, L.; Cheng, Y.; Hou, K.; Tang, L.; Zeng, G. Factors influencing degradation of trichloroethylene by sulfide-modified nanoscale zero-valent iron in aqueous solution. Water Res. 2018, 135, 1–10. [Google Scholar] [CrossRef]
  86. Zhu, F.; Ma, S.; Liu, T.; Deng, X. Green synthesis of nano zero-valent iron/Cu by green tea to remove hexavalent chromium from groundwater. J. Clean. Prod. 2018, 174, 184–190. [Google Scholar] [CrossRef]
  87. Lico, D.; Vuono, D.; Siciliano, C.; Nagy, J.B.; De Luca, P. Removal of unleaded gasoline from water by multi-walled carbon nanotubes. J. Environ. Manag. 2019, 237, 636–643. [Google Scholar] [CrossRef] [PubMed]
  88. Liang, J.; Liu, J.; Yuan, X.; Dong, H.; Zeng, G.; Wu, H.; Wang, H.; Liu, J.; Hua, S.; Zhang, S.; et al. Facile synthesis of alumina-decorated multi-walled carbon nanotubes for simultaneous adsorption of cadmium ion and trichloroethylene. Chem. Eng. J. 2015, 273, 101–110. [Google Scholar] [CrossRef]
  89. Mdlovu, N.V.; Lin, K.-S.; Chen, C.-Y.; Mavuso, F.A.; Kunene, S.C.; Carrera Espinoza, M.J. In-situ reductive degradation of chlorinated DNAPLs in contaminated groundwater using polyethyleneimine-modified zero-valent iron nanoparticles. Chemosphere 2019, 224, 816–826. [Google Scholar] [CrossRef]
  90. Ou, J.-H.; Sheu, Y.-T.; Tsang, D.C.W.; Sun, Y.-J.; Kao, C.-M. Application of iron/aluminum bimetallic nanoparticle system for chromium-contaminated groundwater remediation. Chemosphere 2020, 256, 127158. [Google Scholar] [CrossRef] [PubMed]
  91. Wang, T.; Liu, Y.; Wang, J.; Wang, X.; Liu, B.; Wang, Y. In-situ remediation of hexavalent chromium contaminated groundwater and saturated soil using stabilized iron sulfide nanoparticles. J. Environ. Manag. 2019, 231, 679–686. [Google Scholar] [CrossRef] [PubMed]
  92. Xie, W.; Liang, Q.; Qian, T.; Zhao, D. Immobilization of selenite in soil and groundwater using stabilized Fe–Mn binary oxide nanoparticles. Water Res. 2015, 70, 485–494. [Google Scholar] [CrossRef] [PubMed]
  93. Dong, H.; Jiang, Z.; Deng, J.; Zhang, C.; Cheng, Y.; Hou, K.; Zhang, L.; Tang, L.; Zeng, G. Physicochemical transformation of Fe/Ni bimetallic nanoparticles during aging in simulated groundwater and the consequent effect on contaminant removal. Water Res. 2018, 129, 51–57. [Google Scholar] [CrossRef]
  94. Huang, Y.; Keller, A.A. EDTA functionalized magnetic nanoparticle sorbents for cadmium and lead contaminated water treatment. Water Res. 2015, 80, 159–168. [Google Scholar] [CrossRef] [Green Version]
  95. Li, D.; Egodawatte, S.; Kaplan, D.I.; Larsen, S.C.; Serkiz, S.M.; Seaman, J.C. Functionalized magnetic mesoporous silica nanoparticles for U removal from low and high pH groundwater. J. Hazard. Mater. 2016, 317, 494–502. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  96. Alani, O.A.; Ari, H.A.; Offiong, N.-A.O.; Alani, S.O.; Li, B.; Zeng, Q.-r.; Feng, W. Catalytic Removal of Selected Textile Dyes Using Zero-Valent Copper Nanoparticles Loaded on Filter Paper-Chitosan-Titanium Oxide Heterogeneous Support. J. Polym. Environ. 2021, 29, 2825–2839. [Google Scholar] [CrossRef]
  97. Ari, H.A.; Alani, O.A.; Zeng, Q.-r.; Ugya, Y.A.; Offiong, N.-A.O.; Feng, W. Enhanced UV-assisted Fenton performance of nanostructured biomimetic α-Fe2O3 on degradation of tetracycline. J. Nanostruct. Chem. 2021. [Google Scholar] [CrossRef]
  98. Dissanayake, N.M.; Current, K.M.; Obare, S.O. Mutagenic Effects of Iron Oxide Nanoparticles on Biological Cells. Int. J. Mol. Sci. 2015, 16, 23482–23516. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  99. Current, K.M.; Dissanayake, N.M.; Obare, S.O. Effect of Iron Oxide Nanoparticles and Amoxicillin on Bacterial Growth in the Presence of Dissolved Organic Carbon. Biomedicines 2017, 5, 55. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  100. Du, W.; Xu, Y.; Yin, Y.; Ji, R.; Guo, H. Risk assessment of engineered nanoparticles and other contaminants in terrestrial plants. Curr. Opin. Environ. Sci. Health 2018, 6, 21–28. [Google Scholar] [CrossRef]
  101. Shrivastava, M.; Srivastav, A.; Gandhi, S.; Rao, S.; Roychoudhury, A.; Kumar, A.; Singhal, R.K.; Jha, S.K.; Singh, S.D. Monitoring of engineered nanoparticles in soil-plant system: A review. Environ. Nanotechnol. Monit. Manag. 2019, 11, 100218. [Google Scholar] [CrossRef]
  102. Hristozov, D.R.; Gottardo, S.; Critto, A.; Marcomini, A. Risk assessment of engineered nanomaterials: A review of available data and approaches from a regulatory perspective. Nanotoxicology 2012, 6, 880–898. [Google Scholar] [CrossRef]
  103. Gómez-Sagasti, M.T.; Epelde, L.; Anza, M.; Urra, J.; Alkorta, I.; Garbisu, C. The impact of nanoscale zero-valent iron particles on soil microbial communities is soil dependent. J. Hazard. Mater. 2019, 364, 591–599. [Google Scholar] [CrossRef]
  104. Dong, H.; Xie, Y.; Zeng, G.; Tang, L.; Liang, J.; He, Q.; Zhao, F.; Zeng, Y.; Wu, Y. The dual effects of carboxymethyl cellulose on the colloidal stability and toxicity of nanoscale zero-valent iron. Chemosphere 2016, 144, 1682–1689. [Google Scholar] [CrossRef]
  105. Chaithawiwat, K.; Vangnai, A.; McEvoy, J.M.; Pruess, B.; Krajangpan, S.; Khan, E. Impact of nanoscale zero valent iron on bacteria is growth phase dependent. Chemosphere 2016, 144, 352–359. [Google Scholar] [CrossRef] [PubMed]
  106. Cheng, Y.; Dong, H.; Lu, Y.; Hou, K.; Wang, Y.; Ning, Q.; Li, L.; Wang, B.; Zhang, L.; Zeng, G. Toxicity of sulfide-modified nanoscale zero-valent iron to Escherichia coli in aqueous solutions. Chemosphere 2019, 220, 523–530. [Google Scholar] [CrossRef]
  107. Li, Z.; Wang, L.; Wu, J.; Xu, Y.; Wang, F.; Tang, X.; Xu, J.; Ok, Y.S.; Meng, J.; Liu, X. Zeolite-supported nanoscale zero-valent iron for immobilization of cadmium, lead, and arsenic in farmland soils: Encapsulation mechanisms and indigenous microbial responses. Environ. Pollut. 2020, 260, 114098. [Google Scholar] [CrossRef] [PubMed]
  108. Lam, C.W. Pulmonary Toxicity of Single-Wall Carbon Nanotubes in Mice 7 and 90 Days After Intratracheal Instillation. Toxicol. Sci. 2003, 77, 126–134. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  109. Song, B.; Chen, M.; Ye, S.; Xu, P.; Zeng, G.; Gong, J.; Li, J.; Zhang, P.; Cao, W. Effects of multi-walled carbon nanotubes on metabolic function of the microbial community in riverine sediment contaminated with phenanthrene. Carbon 2019, 144, 1–7. [Google Scholar] [CrossRef]
  110. Vilardi, G.; Mpouras, T.; Dermatas, D.; Verdone, N.; Polydera, A.; Di Palma, L. Nanomaterials application for heavy metals recovery from polluted water: The combination of nano zero-valent iron and carbon nanotubes. Competitive adsorption non-linear modeling. Chemosphere 2018, 201, 716–729. [Google Scholar] [CrossRef]
  111. Zhang, R.; Zhang, N.; Fang, Z. In situ remediation of hexavalent chromium contaminated soil by CMC-stabilized nanoscale zero-valent iron composited with biochar. Water Sci. Technol. 2018, 77, 1622–1631. [Google Scholar] [CrossRef] [Green Version]
  112. Qian, L.; Chen, Y.; Ouyang, D.; Zhang, W.; Han, L.; Yan, J.; Kvapil, P.; Chen, M. Field demonstration of enhanced removal of chlorinated solvents in groundwater using biochar-supported nanoscale zero-valent iron. Sci. Total Environ. 2020, 698, 134215. [Google Scholar] [CrossRef]
  113. Alabresm, A.; Chen, Y.P.; Decho, A.W.; Lead, J. A novel method for the synergistic remediation of oil-water mixtures using nanoparticles and oil-degrading bacteria. Sci. Total Environ. 2018, 630, 1292–1297. [Google Scholar] [CrossRef] [PubMed]
  114. Czinnerová, M.; Vološčuková, O.; Marková, K.; Ševců, A.; Černík, M.; Nosek, J. Combining nanoscale zero-valent iron with electrokinetic treatment for remediation of chlorinated ethenes and promoting biodegradation: A long-term field study. Water Res. 2020, 175, 115692. [Google Scholar] [CrossRef] [PubMed]
  115. Boente, C.; Sierra, C.; Martínez-Blanco, D.; Menéndez-Aguado, J.M.; Gallego, J.R. Nanoscale zero-valent iron-assisted soil washing for the removal of potentially toxic elements. J. Hazard. Mater. 2018, 350, 55–65. [Google Scholar] [CrossRef] [PubMed]
  116. Qu, G.; Kou, L.; Wang, T.; Liang, D.; Hu, S. Evaluation of activated carbon fiber supported nanoscale zero-valent iron for chromium (VI) removal from groundwater in a permeable reactive column. J. Environ. Manag. 2017, 201, 378–387. [Google Scholar] [CrossRef]
  117. Huang, J.; Yi, S.; Zheng, C.; Lo, I.M.C. Persulfate activation by natural zeolite supported nanoscale zero-valent iron for trichloroethylene degradation in groundwater. Sci. Total Environ. 2019, 684, 351–359. [Google Scholar] [CrossRef] [PubMed]
Water 13 02186 g001 550
Figure 1. Metal ions removal using nZVI (A) is the mechanism and (B) is the particles aggregations. Reprinted with permission from [19] (2021, Elsevier).
Figure 1. Metal ions removal using nZVI (A) is the mechanism and (B) is the particles aggregations. Reprinted with permission from [19] (2021, Elsevier).
Water 13 02186 g001
Water 13 02186 g002 550
Figure 2. Remediation of an aquifer contaminated by DNAPLs injecting nZVI suspensions directly at the sources of contamination. Reprinted with permission from [83] (2014, Elsevier).
Figure 2. Remediation of an aquifer contaminated by DNAPLs injecting nZVI suspensions directly at the sources of contamination. Reprinted with permission from [83] (2014, Elsevier).
Water 13 02186 g002
Water 13 02186 g003 550
Figure 3. Groundwater remediation using Fe/FeS nanoparticles. Reprinted with permission from [80] (2017, Elsevier).
Figure 3. Groundwater remediation using Fe/FeS nanoparticles. Reprinted with permission from [80] (2017, Elsevier).
Water 13 02186 g003
Water 13 02186 g004 550
Figure 4. Step of injection procedure. Reprinted with permission from [112] (2020, Elsevier).
Figure 4. Step of injection procedure. Reprinted with permission from [112] (2020, Elsevier).
Water 13 02186 g004
Water 13 02186 g005 550
Figure 5. Soil washing assisted nZVI nanoremediation. Reprinted with permission from [115] (2018, Elsevier).
Figure 5. Soil washing assisted nZVI nanoremediation. Reprinted with permission from [115] (2018, Elsevier).
Water 13 02186 g005
Table
Table 1. Recent studies that employed nanoremediation methods for soil remediation.
Table 1. Recent studies that employed nanoremediation methods for soil remediation.
NanomaterialContaminantExperimental ConditionImportant ResultsRef.
PVP-nZVITrichloroethyleneTCE initial concentration 1 mg kg−1;
PVP-nZVI dosage 0.01 g g−1		The size of papered PVP-nZVI was around 70 nm. The isoelectric point was around 8.5.
In terms of TCE removal efficiency of the investigated system, the removal of TCE was around 84.73%.		[64]
nZVICr(VI)Five ratios were tested (1000/140; 1000/70; 1000/35; 1000/23, 1000/11 mg mg−1);
nZVI injection pressure (10,30,100) kPa;
Cr(VI) initial concentration 800 mg kg−1		The removal efficiency at (1000/11) mg mg−1 ratio was 98% whereas at (1000/140) mg mg−1 was 18%. As the pressure increased, the contaminant leaching increased, thus the pressure of 30 kPa was more efficient.[65]
nZVI and Cu modified nZVI NitrateInitial nitrate concentration (45 mg L−1); NO3-N
nZVI and Cu modified (10 g per layer);
Flow rate (5 mL min −1);
Residence time (99 min)		One layer nZVI removed more than 97% of nitrate, whereas two-layer Cu-modified nZVI achieved complete removal. [66]
Rhamnolipid modified nZVICd(II), Pb(II)Sediment wight 0.5, 2 g;
R-nZVI concentration 2.5, 10 mL with 0.01, 0.03, 0.05,0.1, 0.2 wt%;
Reaction time 0, 7, 14, 21, 28, 35, 42 days		R-nZVI was effective for heavy metal immobilization on river sediment.[67]
nZVIDDTnZVI dosage (5% w/w);
reaction time (60 min)		DDT removal by nZVI and µZVI was 85% and 11%, respectively, thus revealing the superiority of using nZVI over µZVI on DDT removal from contaminated soil.[19]
Multi-walled carbon nanotubes (MWCNTs)Total petroleum hydrocarbons (TPH)TPH initial concentration 11 000 mg kg−1;
microwave treatment 15, 30, 60 s; CTNs concentration 1, 2.5, 5 wt%		Microwave irradiation time and CTNs concentration significantly affect the removal of TPH from contaminated soil. [68]
MWCNTsCr(VI)Cr(VI) initial concentration 5–60 mg L−1;
Citric acid concentration 25–250 mg L−1;
MWCNTs concentration 1.25 mg L−1		At pH 5.0, Cr(VI) adsorption capacity could reach 8.09 and 7.85 mg g−1 by MWCNT-COOH and MWCNT-OH, respectively.
All these data suggest that the catalysis function of CNTs on the reduction of Cr(VI) was decreased by increasing pH		[69]
Modified carbon black nanoparticle (MCBN)Heavy metal and petroleumCd initial concentration 10 mg kg−1;
Ni initial concentration (100 mg kg−1);
Petroleum initial concentration (2000 mg kg−1);
Remediation time 60 days;
MCBN dosage (1% w/w)		The result showed that the availability of heavy metals could significantly decrease by using MNCB in Cd and Ni contaminated soil and enhance the growth of the plant[70]
Single-walled carbon nanotubes (SWCNTs) and MWCNTsdichlorodiphenyltri- chloroethane (DDT) and hexachlorocyclohexane (HCH)SWCNTs and MWCNTs dosage 0.058, 0.145, 0.29 wt%;
DDT initial concentration 3 mg kg−1;
HCH initial concentration l mg kg−1		CNTs could effectively treat DDTs and HCHs, and the optimum condition for the SWCNTs was 0.29 wt% dosage for 4 months. The results suggest that the efficiency of CNTs remediation was highly dependent on dose, type, and sediment–sorbent contact time[71]
MWCNTscrude oilMWNTs concentration 0.1, 0.5, 1 wt%;
Crude oil concentration 0.5, 1, 2.5, 5 wt%;
Remedation time 30 days		The results showed that using MWCNTs can enhance the degradation of hydrocarbons by increasing the total microbial population[72]
MWCNTs and ACDDT, HCHDDT initial concentration 14 ng g−1;
HCH initial concentration (5.5 ng g−1);
AC dosage (1, 2) wt%
MWCNTs dosage (1, 2) wt%
Reaction time (30, 45, 150) days		The results suggest that the Ac was more effective than MWCNTS due to its great specific surface area. These findings revealed the promising of using carbon materials as in situ soil remediation[73].
Al2O3, SiO2, TiO2Zn, Ni, CdMetal NPs (Al2O3, SiO2, TiO2) dosage 1, 3 wt%;
Remediation time 30 days		The results showed that SiO2 NPs were feasible sorbent for reduction of the three metals (Zn, CD, Ni) in calcareous soils, whereas Al2O3 NPs were effective for immobilizing Cd and Zn in non-calcareous soil[74]
Biochar-supported iron phosphate nanoparticleCdRemediation time 28 days;
Cd initial concentration (4.25–132.23) mg kg−1		The results indicated that after 25 days, 81.3% of Cd was reduced.[75]
Goethite nanospheres (nGoethite) and nZVIAsnZVI dosage (0.5, 2, 5,10) wt%;
nGoethite dosage 0.2, 1, 2.5 wt%;
As initial concentration 85 mg kg−1		Both nGoethite and nZVI are promising nanomaterials for As immobilization from contaminated soil. Moreover, remediation by a small dosage of nGoethite seems a promising nanoremediation for effective reduction of As in soil.[76].
MNPsCd, PbCd initial concentration 10.91 mg kg−1;
Pb initial concentration 190 mg kg−1		The results showed that the organic content of the soil negatively affected the removal of the residual heavy metals, whereas the use of MNPs did not change the chemical composition of the soil.[77]
Fe3O4@C-COOH MNPsPbPb initial concentration (737.34) mg kg−1;
Fe3O4@C-COOH MNPs dosage (0.6,
1.3, 2.0, 2.6, 3.3, 4.0) wt%;
Remediation time 10 days		The migration of Pb was highly reduced, achieving a high degree of remediation of Pb-contaminated soil.
The results suggest that Fe3O4@C-COOH MNPs was a promising remediations technology for lead-contaminated soil		[52]
MNPsAs, PAH, TPHMNPs dosage 0.2, 1, 2, 5 wt%;
As initial concentration 1305 mg kg−1;
PAHs initial concentration 6777 µg kg−1;
TPH initial concentration 384 mg kg−1		MNPs dosage of 1% could immobilize 42% of As, whereas 92.3% was immobilized at 5% dosage. In terms of organic pollutants, at the lowest MNPs dosage, the reductions of PAHs and TPH were 89% and 49%, respectively[78]
Table
Table 2. Recent studies that employed nanoremediation methods for water and groundwater remediation.
Table 2. Recent studies that employed nanoremediation methods for water and groundwater remediation.
NanomaterialContaminantExperimental ConditionImportant ResultsRef.
(PEI-nZVI)Perchloroethene (PCE), trichloroethylene (TCE) and 1,2-dichloroethene (1,2-DCE)TCE initial concentration 94,000 µg L−1;
1,2-DCE initial concentration 2800 µg L−1		The result showed full removal of the three DNAPLs after one day from the (PEI-nZVI) injection.[84,89]
Sulfide-modified nanoscale zero-valent iron (S-nZVI)Trichloroethylene (TCE) TCE initial concentration 20 mg L−1;
S-nZVI to BC mass ratio 1:1, 1:3, 3:3;
Initial pH 3, 5, 7, 9; pyrolysis temperatures 300, 500, 700 °C.		The results indicated that the mass ratio of S-nZVI to BC could satisfy the amount of degradation and adsorption of TCE. The pyrolysis temperatures could influence the TCE degradation and adsorption by changing the physicochemical properties of BC. The initial pH has no significant effect on the total TCE removal, whereas at high pH, the degradation was enhanced.[20]
S-nZVITrichloroethylene (TCE) Initial pH 5.57, 7.10, 8.02;
TCE initial concentration 30 mg L−1;
Aging time 10, 20, and 30 days		The result indicated that Fe/S molar ratio and initial pH remarkably affected the TCE removal, where a higher TCE removal was obtained at Fe/S molar ratio of 60 at pH above than 7.[85]
nZVI/CuCr(VI)Cr(VI) initial concentration 10, 10, 15 mg L−1; nZVI/Cu concentration 0.4 g L−1; pH 5, 7, 9; temperature 293, 303, 313 KAt optimum condition (pH = 5, temperature 303 K, the Cr(VI) removal efficiency was 94.7%.[86]
nZVICu(II), Ni(II)nZVI dosage 0, 1, 5 wt%;
Cu initial concentration 1000 mg kg−1;
Ni initial concentration 2000 mg L−1		the presence of Cu affected the immobilization of Ni, whereases the presence of Ni did not affect the immobilization of Cu.
The use of 5% dosage completely removed Cu and Ni from water samples, where in soil samples, 5% dosage achieved 54% and 21% immobilization for Ni and Cu, respectively.		[21]
MWCNTsCr(VI)MWCNTs dosage 10–50 g L−1;
Cr(VI) initial concentration 11 mg L−1 and 250 µg L−1; Contact time 24 h; pH 3–9		The adsorption process was increased by increasing the MWCNTs concentration. At pH 8, the adsorption percentage increased from 85% to 100% as the concentration of MWCNTs increased from 10 g L−1 to 50 g L−1.[22]
MWCNTsUnleaded gasolineMWCNTs dosage 0.2–0.8 g;
Reaction time 5–120 min		The result indicated that a small amount of MWCNTs (0.7 g) within 5 min could remove a high percentage of unleaded gasoline.[87]
Al2O3/MWCNTsCd(II), TCEAl2O3/MWCNTs dosage 1 g L−1;
Cd(II)/TCE initial concentration 1 mg L−1;
pH (4–10)		The result showed that the maximum adsorption capacities achieved by Al2O3/MWCNTs were 19.84 mg g−1 for Cd(II) and 27.21 mg g−1 for TCE. The results suggest that Al2O3/MWCNTs could be a promising technology for Cd(II)- and TCE-contaminated groundwater remediations.[88]
Fe/Al BNPsCr(VI)Cr(VI) initial concentration 4–200 mg L−1; (Fe/Al) BNPs and (Al/Fe) BNPs dosage (2.5) g L−1Removal efficiency was 1.47 g g−1 when (Fe/Al) BNPs were used and 0.07 g g−1 when(Al/Fe) BNPs was used.[90]
Iron sulfide NPs (FeS NPs)Cr(VI)Cr(VI) initial concentration 204.84,
3464 mg kg−1; FeS NPs dosage (28.2, 42.3, 67.7, 84.6 m 117.0) mg L−1		The batch test results indicated that a high removal efficiency (1046.1 mg Cr(VI) per gram FeS NPs) was achieved when FeS NPS was used. This high removal efficiency could be attributed to three mechanisms: reduction, adsorption, and co-precipitation. In addition, they found that the pH significantly affected the Cr(VI) removal using FeS NPs.[91]
Fe-Me binary oxide NPs.Selenite (Se(IV))Se(IV) initial concentration 0–10 mg L−1;
Fe-Mn NPs dosage 0.05 g L−1;
pH 7		The results showed that high Se(IV) uptake was noticed at a pH range of 5–8, a typical groundwater range. The adsorption capacity was determined according to Langmuir maximum capacity, where it was 109 mg Se(IV) per g Fe-Me NPs.[92]
Fe/Ni BNPsTetracyclineAgeing time 5–90 days; Fe/Ni BNPs dosage 1 g L−1; Ni content (1,3,5) wt%;
TC initial concentration 100 mg L−1		The results showed that the aging time plays significant roles in TC removal. The reactivity of Fe/Ni BNPs stayed the same up to 2 days as the removal efficiency of TC was in the range of (82.3–92.5)%. As the aging time increased to 5–15 days, the removal efficiency of TC decreased by 20–50%, to reach around 50%, due to oxidation and aggregation of particles. Finally, the removal efficacy of TC by 90 days aged Fe/Ni BNPs was around 30%.[93]
FeS-coated iron (Fe/FeS) MNPsCr(VI)S/Fe molar ratio 0, 0.070, 0.138, 0.207; pH 3.5, 5, 7.1, 9; Cr(VI) initial concentration 10, 15, 25, 35, 50, 80 mg L−1 Increasing the S/Fe molar ratio to 0.138 decreased Cr(VI) removal by 42.8%. However, a further increase to 0.207 increased the removal efficiency by 63% within 72 h. Moreover, the results indicated that the adsorption process of Cr(VI) by Fe/FeS at S/F molar ratio of 0.207 was fitted a pseudo-second-order kinetic model, and the sorption capacity was 69.7 mg g−1, which was simulated by the Langmuir isotherm model[80]
Magnetic ligand nanoparticleCd(II), Pb(II)Cd, Pb initial concentration 1–100 mg L−1;
pH 4–10; Mag-Ligand dosage 0.2 g L−1		The results showed high performance of Mega-ligand as Cd and Pb were removed from contaminated water quickly, Cd was removed in less than 2 h, and Pb in less than 15 min. The performance of Mega-legend in terms of Cd and Pb was not affected by pH (3–10). In addition, the full regeneration process could be achieved by washed Mega-legend easily by 1% HCl. The results suggest that modified Mega-legend is a feasible nanoparticle for efficient, rapid, and convenient removal of Cd and Pb from the contaminated aquatic system.[94]
MMSNPsU(VI)U(VI) concentration 2.5 × 10−5 M;
MMSNPs dosage 0.075 g in 7.5 mL artificial groundwater		The result showed that MMSNPs were efficient for U(VI) removal in the pH range of (3.5–9.6) for artificial groundwater. They found that MMSNPs adsorption capacity can reach 133 g U(VI) per g MMSNPs[95]
Table
Table 3. Recent studies employed the combination of nanoremediation technologies with other remediation methods.
Table 3. Recent studies employed the combination of nanoremediation technologies with other remediation methods.
NanomaterialContaminantExperimental ConditionsImportant ResultsRef.
CNTs-nZVICr(VI), Se, CoDosage 3 g L−1; Initial concentration 1–10 mg L−1; pH 6–8The result indicated that for Cr(VI), the main removal mechanism was reduction, whereas adsorption was the predominant mechanism for the metals. The results showed that the Cr(VI) removal efficiency was 100% when nZVI was used alone without the effect of pH change, whereas it decreased to around 90% when CNTs–nZVI nanocomposite was used. On the other hand, using CNTs-nZVI showed high removal efficiency for Se and Co at 90% and 80%, respectively.[110]
CMC-nZVI/BCCr(VI)CMC-nZVI/BC dosage 11, 27.5, 55 kg g−1; Cr(VI) initial concentration 800 mg kg−1The results indicate that, after 21 days, the immobilization efficiency of Cr(VI) was 19.7, 33.3, and 100% when the dosage of CMC-nZVI/BC was 11, 27.5, and 55 g Kg−1, respectively.[69]
Biochar-nZVIChlorinated solventsnZVI dosage (30) g L−1; injection depth (3.5, 4.5, 5.5) mThe field study results demonstrated a sharp reduction of chlorinated solvents in the 24 h after the first injection of nZVI, but within the next two weeks, the re-bond of the concentrations in groundwater was observed. However, the implementation of biochar-nZVI highly improved the removal of the chlorinated solvent from groundwater for 42 days. The results suggest that biochar-nZVI is a promising combined technology for chlorinated-solvent-contaminated groundwater remediation.[112]
nZVI combined with compost from organic wasteHydrocarbons (TPH, PAHs) and heavy metalsTPH initial concentration (104.3) mg kg−1; PAHs initial concentration (2.25) mg kg−1The results indicated that the combination of nZVI and compost could decrease the aliphatic hydrocarbons concentration by up to 60% even under uncontrolled conditions. In addition, they observed a remarkable decrease in ecotoxicity in the biopile of the soil.[29].
PVP-coated magnetite NPs with oil-degrading bacteriaCrude oilOil initial concentration (375) mg L−1; NPs dosage (18) mg L−1The result indicated that NPs alone removed around 70% of high oil concentration after 1 h. However, the removal efficiency did not increase due to the saturation of NPs. Bioremediation by oil-degrading bacteria removed 90% of oil after 48 h. Finally, the combination of NPs and oil-degrading bacteria could completely remove the oil within 48 h[113]
nZVI-EKChlorinated ethenes (CEs)nZVI dosage 3 g L−1; DC voltage 24 VThe results indicated a rapid decrease in cis-1,2-dichloroethene (cDCE) by around 70%, followed by new geochemical conditions as a degradation product of CE (ethene, ethane, and methane) was observed. These new conditions enhanced the growth of soil and ground bacteria such as organohalide-respiring bacteria. The results suggest that nZVI-EK remediation technology not only is a promising method for CE remediation from soil and groundwater but also enhanced the bacteria availability in soil and groundwater.[114]
Soil washing assessed nZVIAs, Cu, Hg, Pb, SbnZVI dosage (16) wt%The results showed that a high recovery yield was obtained for Pb, Cu, and Sb in the magnetically separated fraction, whereas Hg concentrated in the non-magnetic fraction. Taking everything into account, the soil washing efficiency was enhanced by adding nZVI, especially for a larger fraction. The results suggest that the investigated methodology open the door for the use of NPs in soil washing remediation.[115]
ACF-nZVICr(VI)Cr(VI) initial concentration (5, 10) mg L−1The results indicated that the aggregation of nZVI could be inhabited by the presence of ACF, which increases the nZVI reactivity and Cr(VI) removal efficiency. The removal efficiency of Cr(VI) decreased with increasing Cr(VI) initial concentration, whereas, in an acidic environment, full removal (100%) of Cr(VI) was observed in 1 h reaction time. The proposed removal mechanism consisted of two steps: the first step was the physical adsorption of Cr(VI) on the ACF-nZVI surface area or inner layer, while the second step was a reduction of Cr(VI) to Cr(III) by nZVI[116]
PS-Z/nZVITCETCE initial concentration (0.15) mM; Z/nZVI dosage (84) mg L−1;
PS concentration (1.5) mM		The results indicated that Z/nZVI showed high ability for PS activation (1.5 mM), and high removal efficiency (98.8%) of TCE was observed at pH 7 within 2 h. Moreover, the PS-Z/nZVI system showed high efficiency in terms of TCE for a wide range of pH (4–7).[117]
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Alazaiza, M.Y.D.; Albahnasawi, A.; Ali, G.A.M.; Bashir, M.J.K.; Copty, N.K.; Amr, S.S.A.; Abushammala, M.F.M.; Al Maskari, T. Recent Advances of Nanoremediation Technologies for Soil and Groundwater Remediation: A Review. Water 2021, 13, 2186. https://doi.org/10.3390/w13162186

AMA Style

Alazaiza MYD, Albahnasawi A, Ali GAM, Bashir MJK, Copty NK, Amr SSA, Abushammala MFM, Al Maskari T. Recent Advances of Nanoremediation Technologies for Soil and Groundwater Remediation: A Review. Water. 2021; 13(16):2186. https://doi.org/10.3390/w13162186

Chicago/Turabian Style

Alazaiza, Motasem Y. D., Ahmed Albahnasawi, Gomaa A. M. Ali, Mohammed J. K. Bashir, Nadim K. Copty, Salem S. Abu Amr, Mohammed F. M. Abushammala, and Tahra Al Maskari. 2021. "Recent Advances of Nanoremediation Technologies for Soil and Groundwater Remediation: A Review" Water 13, no. 16: 2186. https://doi.org/10.3390/w13162186

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop