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Review

Graphene Composites for Lead Ions Removal from Aqueous Solutions

by
Mukesh Kumar
1,*,
Jin Suk Chung
2 and
Seung Hyun Hur
2,*
1
Department of Chemistry, Sri Aurobindo College, University of Delhi, Delhi-110017, India
2
School of Chemical Engineering, University of Ulsan, Daehakro 93, Namgu, Ulsan 680-749, Korea
*
Authors to whom correspondence should be addressed.
Appl. Sci. 2019, 9(14), 2925; https://doi.org/10.3390/app9142925
Submission received: 3 June 2019 / Revised: 15 July 2019 / Accepted: 15 July 2019 / Published: 22 July 2019
(This article belongs to the Special Issue Nanocomposites for the Sustainable Environment)
Browse Figures
Versions Notes

Abstract

:
The indiscriminate disposal of non-biodegradable, heavy metal ionic pollutants from various sources, such as refineries, pulp industries, lead batteries, dyes, and other industrial effluents, into the aquatic environment is highly dangerous to the human health as well as to the environment. Among other heavy metals, lead (Pb(II)) ions are some of the most toxic pollutants generated from both anthropogenic and natural sources in very large amounts. Adsorption is the simplest, efficient and economic water decontamination technology. Hence, nanoadsorbents are a major focus of current research for the effective and selective removal of Pb(II) metal ions from aqueous solution. Nanoadsorbents based on graphene and its derivatives play a major role in the effective removal of toxic Pb(II) metal ions. This paper summarizes the applicability of graphene and functionalized graphene-based composite materials as Pb(II) ions adsorbent from aqueous solutions. In addition, the synthetic routes, adsorption process, conditions, as well as kinetic studies have been reviewed.

Graphical Abstract

Highlights
  • Contaminated waste water is one of the most serious risks for living organisms as well as to the environment.
  • Nanotechnology offers best expectations over traditional technologies for wastewater treatment.
  • Adsorption technology is the phenomenon of adhesion of solid substances onto the surface of adsorbent.
  • Graphene-based nanoadsorbents exhibited a great potential towards effective removal of lead ions from aqueous solution.
  • Graphene preparation, characterization, and applications of graphic-based composites for the removal of lead ions from aqueous solution have been discussed.

1. Background

Water decontamination is one of the most serious challenges among scientists globally due to the increasing population, pollution, and global warming [1,2,3,4,5]. Wastewater from developing industries, such as chemical manufacturing, metallurgical, battery manufacturing, papermaking, and mining industries produce a very large amount of various toxic pollutants in the form of heavy metal ions [6,7,8,9]. Excess heavy metal ions concentration in wastewater is a serious risk to public health as well as to other living organisms on Earth [10,11,12]. These toxic heavy metal pollutants are widely found in the Earth’s crust which tends to bioaccumulate in living organisms; they are non-biodegradable, which can cause various diseases, genetic disorders, and lethal ecological effects [12,13,14,15]. Heavy metal ions in aqueous media pose several toxic threats to the human health as well as to the other living organisms even at low concentrations. As per the regulatory system of the WHO (World Health Organization), the permissible concentration of Pb(II) (Lead (II)) in wastewater is approximately 0.01mg/L [16,17,18]. Moreover, the excess exposure of Pb(II) can lead to irreversible brain damage, cardiovascular disease, cognitive impairment, encephalopathy disease symptoms and even death [19,20,21,22]. Pb(II) is also extremely toxic to the nervous system, kidneys, and may lead to a wide range of human health issues such as nausea, anemia, infertility, coma, convulsions, hemochromatosis, renal failure, cancer, adverse effects on the metabolism and intelligence, and dermatitis brass chills, and cramps in the calves [12,14,23,24,25,26,27].
The current tight regulatory systems do not allow the release of heavy metal ions-contaminated wastewaters into the environment and require the removal of all toxic pollutants before discharging. Therefore, the development of efficient and economical novel materials and technologies for the effective removal of metal ion pollutants are required. Several traditional techniques have been used for the removal of heavy metal ions from aqueous medium, including reverse osmosis, precipitation, biosorption, ion-exchange, electrochemical processes, membrane filtration, irradiation, coagulation, and adsorption [28,29,30,31,32,33,34,35,36,37,38,39,40]. Table 1 lists the techniques used for Pb(II) ions removal from the wastewaters. The main disadvantages of conventional techniques include high cost, metallic sludge generation, incomplete removal, and disposal of secondary waste. Therefore, a cost effective, potential and convenient decontamination technology for wastewater treatment is highly desirable. The high efficiency, cost-effective, and simple operation makes adsorption technology one of the most promising technology for the effective removal of the heavy metal ions from the aqueous solution which adsorb metallic ions at solid-liquid interfaces [41,42,43,44,45,46,47,48,49]. On the other hand, adsorption technology has several challenges, such as selective recovery and reuse of valuable adsorbents and pollutants in the presence of humic substances [50,51]. Adsorbents developed with favorable structures, morphologies, superior adsorption capacities, and ease of separation are a major focus of the current research [26,52,53,54,55,56,57,58,59,60]. Recently, the development of nanotechnology has attracted considerable attention due to the remarkable potential of the nanoadsorbents for the selective and effective removal of ionic pollutants from aqueous solution when compared with the traditional adsorbents [13,33,61,62,63,64,65,66]. The nanoadsorbents play a major role in the separation of heavy metal ions because they are effective sorbents due to their unique structural properties and specific adsorption tendency. Nanoadsorbents have several unique advantages over conventional adsorbents due to their large specific surface area to volume ratio, tunable pore size, regeneration, reusability etc. [33,56,67,68,69,70,71].
Carbon (carbon nanotubes (CNTs), fullerenes, graphene, and graphene derivatives) based adsorbent materials are being used for the effective removal of the heavy metal ions because of their extraordinary high surface area to volume ratio and light weight as compared to other materials [66,96,97]. Currently, adsorbents based on the carbon nanotubes [98,99], activated carbon [100,101,102,103,104,105], graphene/ graphene oxide (GO) [60,67,106,107,108,109,110,111,112,113,114,115,116,117], graphene magnetite’s [118,119,120,121,122,123] polymeric adsorbents [124,125,126,127,128,129,130,131,132] and other type of adsorbents [133,134,135,136,137] have attracted substantial attention for the removal of heavy metal ions from the wastewaters. Carbon nanotubes have significant adsorption capacities for the effective removal of heavy metal ions from aqueous solutions as compared to non-functionalized and activated carbon-based adsorbents [99,138,139,140,141,142]. Although, carbon nanotubes-based materials are the promising adsorbents but their high cost and lower availability, limit the large-scale applications as adsorbents. In addition to this, water permeation through CNTs membranes is a major concern which is still unclear even after both the experimentally and molecular dynamic studies. Therefore, economic, readily available, and effective adsorbents are the prime concern of the 21st century for the effective removal of heavy metal ions from wastewaters. Although, the presence of humic substances has strong complexation binding ability with metal ions because of their abundant oxygen-containing functional groups, yet graphene-based adsorbents have been proven the best substituents for the removal of heavy metal ions from aqueous medium [66,67,143]. Therefore, the adsorption behavior of heavy metal ions onto the surface of graphene-based nanoadsorbents is the chief concern of this study.
Graphene, a flat, single-atom thick sheet of sp2-hybridized carbon atoms with a two-dimensional honeycomb densely packed lattice arrangement, is an essential non-classical carbon adsorbent [144]. Graphene has a variety of real-time applications because of its extraordinary excellent thermal, mechanical and electrical properties [145]. Graphene is considered a promising material for the comprehensive adsorption of wide variety of pollutants from aqueous systems owing to its theoretically large specific surface area to volume ratio (≈2675m2/g), high Young’s Modulus (1.06 × 103 Gegapascals) and high thermal conductivity (3 × 103 Watt per meter kelvin) [113,146]. The wet chemical redox process is one of the most effective method for the production of graphene from graphite, where GO is an intermediate with a high density of negatively-charged reactive functional groups, viz. hydroxyl, carboxylic, and epoxy groups [147,148,149]. The presence of several functional groups makes GO soluble in polar and non-polar solvents as the oxygen functionality makes GO hydrophilic and the graphene domain makes GO hydrophobic. All the functional groups present on the edges and on the basal plane of GO play an important role in the heavy metal ions removal process [150]. Therefore, GO could be the best potential scavenger for the effective removal of cationic pollutants through electrostatic interactions between the positively-charged pollutants and negatively-charged functional groups of GO [27,151]. The relative high surface area, surface functionality, and better conductivity of graphene sheets play a key role in the better adsorption of several heavy metal ions through the preconcentration of aqueous medium [67,144]. Nair et al. reported that a few layered thick GO sheet membrane can completely block the passage of pollutants in the form of liquids and gases in a dry state while facilitating the permeation of water vapors [152]. On the other hand, aggregation, which is a major disadvantage of graphene layers, could be prevented partially through its composite formation [41,153]. In addition, composite formation may impart enhanced efficiency for the removal of heavy metal ions from wastewater due to the synergistic effects of the materials used. Electrosorption, a simple, novel, ecofriendly and recently attractive heavy metal ions adsorption technique which does not requires toxic or non-toxic chemicals and involves ideal nanostructured materials with a high surface area (such as activated carbon, carbon nanotubes, and carbon aerogels) onto which an external electric field is applied to remove metal ions from aqueous solutions [93,154,155,156,157]. Hence, this review includes various surface modification approaches and post synthesis, assembly steps, which will enable the exploitation of GO as a novel adsorbent material for cost effective water purification and the removal of heavy metals through graphene and its composites, which may be helpful in the purification of potable and safe drinking water as well as the removal of heavy metal ions from wastewaters and to clean up the environmental problems.

2. Removal of Lead

Pb(II) is one of the most useful heavy metal with wide spectrum applications worldwide. On the other hand, the presence of Pb(II) in aqueous system is a major threat to mankind as well as to the ecosystem owing to its high toxicity. Therefore, removal of Pb(II) ions from the wastewater aqueous system is quite essential to diminish the toxic threats. An adsorption process is largely dependent on the surface area and pore size of the adsorbents, whereas, the adsorption of metal ions is based on chemical adsorption onto specific adsorption sites, i.e., adsorption capacity of an adsorbent increases with the increase of its functional groups [158,159]. Graphene is thanked to have several active functional groups such as carboxylic, hydroxyl, and epoxy functional groups acting as better adsorption sites [160,161,162,163]. Hence, graphene and graphene derivatives due to their easy preparation, surface modifications, bulk availability and high adsorption capacities have been extensively studied for the removal of Pb(II) ions from aqueous system. Graphene based nanoadsorbents preparation, characterization and their applications for the removal of Pb(II) ions from aqueous medium as well as adsorption process and kinetic studies have been reviewed.

2.1. Removal of lead using functionalized GO/ RGO/ GO-aerogel

An adduct of GO and EDTA, was prepared using silylation by reacting N-(trimethoxysilylpropyl) ethyledinediamine triacetic acid (EDTA-silane) with the -OH functionality of the GO layers [164]. Hummer’s and Offeman’s modified double stage oxidation process was used to produce GO. In the first preoxidized step, natural graphite was treated with potassium persulfate and phosphorous pentaoxide in sulfuric acid followed by the oxidation with potassium permanganate, conc. sulfuric acid and hydrogen peroxide. GO was filtered and washed with 0.1 M HCl and deionized water. Resulting GO was then reacted through silylation process with EDTA-silane and was filtered followed by repeatedly washing with methanol and water. For comparison, a reduced GO adduct, EDTA-RGO black was prepared by direct thermal reduction treatment at 300 °C for 30 min. Adsorption isotherms analysis was performed in a plastic vial using 10 mg or 25 mg adsorbent to a 100 or 200 mL solution of Pb(II) ions at room temperature. It is evident that the adsorption of positively-charged metal ions depend on the charge present on the surface of the adsorbents as functionalities [165,166]. Zeta potential of the adsorbents at different pH was determined using Nano-ZS, Zeta Sizer and correlated with the adsorption of Pb(II) ions. At a particular pH, more negative zeta potential indicated the highest carboxylic and hydroxyl functionalities on the surface of EDTA-GO and GO adsorbents than activated carbon and EDTA-RGO was found to be consistent with Boehm’s titration results [167,168,169,170].
The enhanced adsorption for Pb(II) ions from the aqueous solution was observed with an EDTA-GO adduct (Figure 1) when compared with GO and EDTA-RGO adduct. The maximum adsorption capacities of the EDTA-GO adduct and GO for Pb(II) were found to be 479±46 and 328±39mg/g, respectively, which were greater than those of oxidized carbon nanotubes and activated carbon-based adsorbents [164]. The superior performance of EDTA-GO was correlated with the chelating characteristics of EDTA with functionalized graphene sheets. Mainly two adsorption process were considered to be responsible for the improved efficiency of removal of Pb(II) ions with the EDTA-GO adduct, i.e., the ion-exchange reaction process (Scheme 1) between Pb(II) and carboxylic and hydroxyl functional groups responsible for chelate complex formation between Pb(II) and EDTA onto the GO surface, as shown below.
(First adsorption type):
Interactions of Pb(II) ions onto the surface of GO to form the complex:
(Second adsorption type may include):
Complex formation of Pb(II) with –COOH:
The second adsorption mechanism involves the stable complex formation of EDTA with Pb(II) ions for the complete removal of Pb(II) ions from aqueous solution (Scheme 2). After adsorption, Pb(II) equilibrium concentration reached lower than food and drug administration drinking water concentration i.e < 10ppm. Higher adsorption capacity was attributed with the higher stability constant (Log K≈18.0) of Pb(II)-EDTA complex. Langmuir and Freundlich adsorption isotherms exhibited good agreement with the experimental data having a correlation coefficient (R2) 0.975 and 0.933 at pH 6.8 respectively. The adsorption phenomenon rate for Pb(II) ions onto the surface of EDTA-GO was found to be pH dependent. It was noted that as pH of the aqueous medium increased from 5.0 to 8.0, adsorption capacity of EDTA-GO also increased due to chelate formation of Pb(II) with the hydroxyl, carboxylic functional groups of GO and EDTA. Low adsorption at high acidic medium was attributed due to neutralization of COO and O surface charges and relative competition between proton and Pb(II) ions. Lower zeta potential until pH 8.0 indicated that there were enough negative charge density to provide the strong electrostatic attraction between adsorbent’s functional group and Pb(II) ions. However, as the pH of the medium increased from 8.0, zeta potential rise indicated that negative charge density decreased and Pb(II) ions hydrolzse to give Pb(OH)+, Pb(OH)2, [Pb(OH)3], [Pb3(OH)4]2+ [Pb2(OH)2]2+ [Pb6(OH)8]4+ and [Pb4(OH)4]4+ [171,172,173]. As it is desirable to have appropriate both the adsorption and desorption capacities to be an economical and ideal adsorbent, desorption experiments at different pH were carried out using Pb(II) pretreated EDTA-GO to determine desorption capacity. Desorption rate of Pb(II) was found to be maximum in acidic medium as consistent with zeta potential indicated that at lower pH, neutralization of functional groups leads to the competition between proton and Pb(II) ions adsorption [174]. Atomic absorption spectroscopy results were found to be in good agreement indicated that Pb(II) ions could be repeatedly desorbed from EDTA-GO adsorbent even after 10 cycles.
Varadwaj et al. prepared Mg-Al-layered double hydroxide and partially reduced GO (LDH/pRGO) nanocomposites by a two-step process, resulting a three-dimensional highly porous nanocomposite adsorbent [174]. GO nanosheets were obtained using the modified Hummer’s method and in situ homogeneously LDH nanosheets were grown onto the surface of GO by a crystallization and facile supersaturation coprecipitation technique at pH 10 [175]. Typically, a mixed metal solution of Mg(NO)3.6H2O and Al(NO3)3.9H2O and alkaline solution of Na2CO3 and NaOH were added dropwise simultaneously to GO ultrasonicated solution at 10 pH. After the stipulated period of time, precipitate was filtered and washed with deionized water and dried at 100 °C for 24 h. It was supposed that Mg2+ and Al3+ ions form coordination complexes with the carboxylic, hydroxyl and carbonyl functional groups of GO upon simultaneous alkaline precipitating agents and weakened the C=O str. absorption peak in FT-IR (Fourier transform infrared spectroscopy) spectrum at 1729 cm−1 indicating the partial reduction of GO in Mg-Al-LDH/pRGO composite and was in consistent with 0.65 nm shifting of (001) basal spacing X-ray diffraction peak. Disappearance of pRGO diffraction peaks from Mg-Al-LDH-pRGo composite exhibited the complete exfoliation of pRGO sheets. Further, GO and Mg-Al-LDH/pRGO were exploited under nitrogen adsorption-desorption studies which revealed that meso-porous structural morphology related to narrow slit-like pores for GO and interconnected pore network for Mg-Al-LDH/pRGO composite. BET (Brunauer-Emmett-Teller) surface area, pore volume and pore size indicated increasing trend as the metal ion concentration of LDH increases. An increase surface area with crosslinked network is supposed to offer more active sites for better metal ions adsorption from the aqueous solution.
Figure 2 presents pH based adsorption efficiency for Pb(II) for 24 h contact time at 100 mg dm−3 as an initial Pb(II) ion concentration. The highest adsorption efficiency was observed for the Mg-Al-LDH/pRGO composite adsorbent as compared to LDH, GO, and pRGO, which might be correlated with the synergistic effects of LDH and GO. The adsorption efficiency of the adsorbent was found to be lowest in acidic medium and increased with increasing pH of the medium. The lower adsorption in the acidic medium was attributed due to the competitive presence of H+ ions. As the basicity of the medium increased, the concentration of H+ ions decreased, resulting in higher Pb(II) ion adsorption. Owing to the subsequent precipitation of Pb(II) ions as [Pb(OH)], [Pb(OH)2], [Pb(OH)3], [Pb3(OH)4]2+ [Pb2(OH)2]2+ [Pb6(OH)8]4+, and [Pb4(OH)4]4+ in basic medium, the pH of the medium was set to 4.5 for all other experimental studies to avoid precipitation and to confirmed the removal of Pb(II) ions through adsorption [173]. Higher adsorption efficiency was obtained with higher “ x ” values of LDH due to the increasing high surface area and pore volume with increasing “ x ” factor. The pore sizes of 10.97–21.23 nm of the resulting interconnected 3D network allows the easy flow of hydrated Pb(II) ions, which have ~0.4 nm radius. In addition, the availability of more active sites due to the high surface area accounted for the higher adsorption efficiency of the 3D interconnected nano-porous adsorbent. As the adsorption efficiency depends not only on the surface area but also on the interactive strength of the surface functional groups, hence zeta potential was used to explain electrostatic interactions between the adsorbent and adsorbate. Zeta potential decreased as the pH of the medium increased suggesting that there were higher availability of negative charges which were responsible for the strong electrostatic interactions between positively-charged metal ions and negatively-charged adsorbent’s surface.
Effect of temperature is an important factor of study on which the adsorption phenomenon depends because the adsorption rate depends on the solution viscosity, electrostatic interactions between the metal ions and the adsorbent surface, diffusion of the adsorbents and structural morphology of the adsorbent at a particular temperature. These factors are responsible for maximizing Pb(II) ions uptake due to the increased mobility of Pb(II) ions towards active sites of the adsorbents [166,176,177]. It was noted that as the temperature increased, the adsorption capacities of GO and pRGO increased which were ascribed with the decreased viscosity of the medium, increased mobility of Pb(II) ions, and increased pore volume and structural porosity at a higher temperature indicating endothermic nature of adsorption whereas temperature rise sometime may lead to decreased in adsorptive forces affecting adsorption rate [166]. Langmuir adsorption isotherms assumed uniform monolayer surface adsorption. Pb(II) ions adsorption was found to be increased with temperature. Increasing adsorptive strength of adsorbents indicated increasing strong interactions between adsorbents reactive sites and Pb(II) ions with increasing adsorbate temperature [163,166,178].
Thermodynamic parameters viz. Gibbs free energy (ΔG°), enthalpy (ΔΗ°) and entropy (ΔΣ°) obtained indicated spontaneous adsorption process [179]. Negative values for ΔG° demonstrated the spontaneity of adsorption process and adsorption was found to be increased as the temperature increased. Positive values for ΔΗ° and ΔΣ° for 0.5 Mg-Al-LDH/pRGO denoted endothermic adsorption and increased in the disorderliness at solid-solution interface. It was interested to note that the physiosorption was predominated for low “ x ” factor i.e., 1.0 and 3.0 Mg-Al-LDH/pRGO nanocomposites whereas adsorption for GO, pRGO and 0.5 Mg-Al-LDH/pRGO was facilitated by both chemisorption and physiosorption process. Desorption experiments were carried out using 0.1 M HCl and 0.01M EDTA solutions to get insight into the recovery of metal ions on the spent adsorbents and the possible regeneration of the adsorbent for reuse [174]. Both insights may help to minimize the disposal of spent adsorbent, and reduce the production of secondary pollutants. Compared to EDTA solution used, better adsorbent regeneration was achieved with 0.1 mol dm−3 HCl solution, which demonstrated the effective ability of HCl to regenerate the spent adsorbent which could be further reused for other industrial applications, such as electroplating.
Nitrogen-doped graphene aerogels (NGAs) were prepared via a facile one-pot hydrothermal route and used as the electrode material for the electrosorption of Pb(II) ions as depicted in Scheme 3 [180]. The insertion of heteroatoms (strong coordination ability with metal cations) onto carbon and graphene-based nanomaterials enhance the adsorption capacity because heteroatoms can coordinate strongly with heavy metal ions [181]. NGAs was prepared by hydrothermal treatments of GO and urea homogenous suspension for 12 h at 180 °C in Teflone lined autoclave. Resulted samples were immersed in pure water for 72 h to remove impurities by changing water at every 4 h and freeze-dried at −52 °C to obtain NGAs which was used for the electrosorption of Pb(II) ions as paper electrode. Appearance of new XPS (X-ray photoelectron spectroscopy) peaks at 400.0 eV and 285.8 eV indicated the incorporation of nitrogen and C-N bond formation after hydrothermal treatment respectively. Deconvolution spectrum fitted for N 1s into three XPS peaks at 398.1, 399.5, and 401.4 eV were found to be corresponded with pyridinic N, pyrrolic N and graphitic N, respectively.
The electrosorption experiment for Pb(II) was performed using a conventional three-electrode system consisting of NGAs paper, saturated calomel electrode (SCE), and platinum foil as working, reference, auxiliary electrodes, respectively. NGAs paper electrode showed highest electrosorption of Pb(II) ions in the shortest adsorption equilibrium time (within 5 s) at −0.3V (1 mM, pH 4.2) potential applied when compared with GAs, and RGO. The superior electrosorption behavior for Pb(II) could be attributed due to the synergistic effects of both NGAs (with a larger surface area ~434.4 m2 g−1) and incorporated heteroatoms which result electrosorption through the electrostatic attractions derived from an external electric field, electrostatic attraction caused by intrinsic charges on the NGAs and Pb(II), and strong coordination between the doped nitrogen atoms and Pb(II) ions. The highest metal ion removal ratio (%R) was found to decline continuously with an increased initial concentration of Pb(II) ions indicating NGAs as a promising electrode material for Pb(II) ions electrosorption at low concentration [182,183].
The electrosorption data were fitted with Langmuir and Freundlich models. The correlation coefficient (R2) for the Freundlich model was closer to 1 as compared with Langmuir model (0.9778 vs. 0.8651), which suggests that the electrosorption of Pb(II) by the NGAs electrode could be modelled more accurately by the Freundlich model. The R2 value obtained for pseudo first-(0.8465) and second-order kinetics (0.9984) showed that the electrosorption kinetics for Pb(II) onto the NGAs electrode was a better fit to the pseudo-second-order model. Recyclability of used electrode is another important characteristics of electrosorption, i.e., reversible electrosorption and electrodesorption for the same electrode material could be easily achieved using variable potential. NGAs exhibited a highest metal ions removal ratio even after 100 electrosorption/electrodesorption than the previous reports [184,185,186,187].
Graphene oxide/ nickel foam (GO/NF) synthesized via vacuum impregnation method was used for Pb(II) ions electrosorption by Song et al. [188]. To prepare electrode, the appropriate size of NF sheet was washed with acetone followed by hydrochloric acid and deionized water which then immersed in GO solution for 2 h at 40 °C under vacuum. The composite was washed with deionized water and dried under vacuum. GO/NF electrode was installed in Pb(NO3) tank for Pb(II) ions electrosorption studies. pH is an important factor which greatly affects the adsorption of Pb(II) ions hence, studied first. pH study range was set from 3.0 to 6.0, since, Pb(II) ions get precipitated as [Pb(OH)], [Pb(OH)2], [Pb(OH)3], [Pb3(OH)4]2+ [Pb2(OH)]2+ [Pb6(OH)8]4+, and [Pb4(OH)4]4+ above pH 6.0 [189] Electrosorption capacity of GO/NF was found to be increased with decreasing medium acidity. pH 5.0 was found the appropriate condition for electrosorption as the steady adsorption capacity was observed above 5.0 pH. Lower adsorption capacity of GO/NF at low pH was correlated with the competitive adsorption between H+ and Pb(II) ions as reported in literature [189,190]. Whereas, on increasing pH, H+ ions competition weaken and Pb(II) ions adsorption increased. It was interesting to note that GO coating largely enhanced the adsorption capacity of GO/NF (193 mg/g at 100mg/L as initial concentration) for Pb(II) ions without applying any voltages when compared with virgin NF owing that GO had large negatively-charged oxygenated surface which favored Pb(II) ions adsorption. Electrosorption capacity of GO/NF (663mg/g, approx. three times) increased when electric current of 1.2 V was applied at the same initial Pb(II) ions concentration indicated that external electric field driven effectively the adsorption of Pb(II) ions adsorption. Langmuir adsorption isotherms of Pb(II) on GO/NF electrode were found to be better fitted with higher correlation coefficient (R2 = 0.9795) and maximum adsorption capacity (3690.37mg/g) than Freundlich. GO/NF showed extremely higher electrosorption capacity, indicating the great potential for Pb(II) ions adsorption from aqueous system in comparison to other adsorbents. Electrosorption mechanism for Pb(II) ions onto the surface of GO/NF surface was analyzed using XPS indicating new Pb 4f peak at 183.3 eV after successful adsorption. Noticeable decreased in relative C-OH bond area from 26.98% to 7.98% and increased bond area ratio of –C=O from 11.92% to 13.05%, clearly indicated, surface adsorption of Pb(II) ions, facilitated by hydroxyl and carboxylic functional groups. Mono or multilayers coating of GO not only increased surface area of GO/NF but also provided more space for double layer electrosorption/chemisorption of Pb(II) ions.
Electron beam irradiation is another cost-effective and environment friendly method that can be applied to all material phases (i.e., solid, liquid, and gas,) at a low temperatures and can be scaled up easily [172]. Therefore, Bai et al. synthesized GO with a controlled oxygen content using electron beam irradiation and used Pb(II) metal ions adsorption [191]. Before the preparation of GO, graphite was placed on stainless steel plate uniformly and irradiated with different intensity dosages of 6.4 and 19.2 kGy by changing irradiation period of time. GO was prepared using modified Hummer’s method and dried under vacuum for 48 h at 40 °C. Irradiated GO was then examined under the effects of the contact time, pH of the medium, initial concentration of Pb(II) ions (75 mg/L), and ionic strength for Pb(II) ions sorption. After the sorption process, solution was filtered and Pb(II) ion concentrations remaining were examined by inductively coupled plasma with an optical emission spectrometer. The removal capacities of the adsorbent qe (mg/g) were calculated using the equation, qe = (Ci − Ce)V/m, where Ci and Ce are the initial and equilibrium Pb(II) ion concentrations (mg/L), respectively; V is solution volume in mL; and m is amount of the adsorbent in mg. The amount of Pb(II) adsorbed onto the GO surface increased remarkably with increasing adsorption time and the equilibrium was reached within 20 min. Hence, a maximum of 2 h of contact time was found to be adequate to achieve sorption equilibrium. The increased sorption with the irradiation dose and time indicated that higher functionality formed through higher irradiated dosages which were responsible for higher Pb(II) ions sorption onto GO surface. The experimentally obtained Pb(II) ions sorbed amount was very close with the calculated value as per nonlinear pseudo-second-order rate model. The correlation coefficients obtained from the pseudo-second order kinetic model simulations were near to 1.0, indicating that sorption of Pb(II) onto the GO surface might be controlled mainly by the chemical adsorption processes (chemisorption) and the equilibrium sorption capacity was almost proportional to the number of occupied active positions on the GO surface, which increased with increasing irradiation dose. Another important parameter, effects of pH on the adsorption of Pb(II) ions was studied with an initial Pb(II) ions concentration of 75 mg/L and 1.5mg of GOs for 2 h of contact time. The adsorption capacity of the GOs increased with increasing pH from 1-5, as reported previously [164,174]. The hydrogen ion concentration rendered the adsorption of Pb(II) at a lower pH because it neutralized the carboxylic and hydroxyl functionalities. The concentration of negative functional groups, such as COO and O, increased with increasing pH, which were responsible for the better adsorption of Pb(II) at higher pH. Effect of ionic strength on Pb(II) ions adsorption was found fairly negligible and independent in the range of 0.001-0.1 mol/L for different dosages of GO however it was largely dependent on pH which indicated inner-sphere surface complexation (chemisorption) rather than outer-sphere surface complexation of Pb(II) ions onto the GO surface [26,171,192].

2.2. Removal of lead using GO-polymer composites

To prevent the aggregation of GO nanosheets, poly(3-aminopropyltriethoxysilane) (PAS) oligomers were cross-linked three dimensionally with GO nanosheets to obtain a high performance adsorbent, PAS-GO [193]. Three-dimensional crosslinking network was meant to prevent the aggregation of GO nanosheets, to provide easy accessibility for foreign molecules and to introduce a large amount of amino functional groups for better adsorption of Pb(II) ions. Two new absorption peaks in FT-IR spectrum of PAS-GO at 3430 cm−1 for –NH2 stretching and at 2927 cm−1 for –CH2 stretching vibrations indicated oligomers crosslinking. Additionally, a distinct Raman peak at 1120 cm−1 supported the presence of Si-O-Si antisymmetric stretching present in composite material. Pb(II) ions adsorption studies were carried out at different temperature, pH and concentration of adsorbate and the filtrate was used for adsorption kinetics. Figure 3 represents the adsorption performance of PAS-GO, AS-GO, and GO for Pb(II) ions adsorption in aqueous solution.
The Langmuir adsorption isotherms represent the maximum adsorption capacities for PAS-GO as compared to AS-GO and pure GO samples. The highest adsorption capacity of PAS-GO was 312.5 mg/g, which was attributed due to the following factors:
(1)
Multi-armed, three dimensional cross-linked functionality prevented GO nanosheets from aggregation, which may provide easier accessibility for trapping of foreign molecules.
(2)
PAS oligomers chains, providing higher functionality/ binding sites in PAS-GO adsorbent, were supposed to be responsible for the higher adsorption of metal ions.
pH of the medium not only influences the adsorption capacities of the adsorbent but also facilitate selective metal ions adsorption [194,195,196]. Hence, Pb(II) ions adsorption at different pH from 2 to 6 were studied. As it is already discussed that in acidic media there is competition between H+ and Pb(II) ions adsorption, hence, lower adsorption capacity for Pb(II) ions was observed at pH from 2 to 3, while, as the pH of the medium increases to 4, adsorption capacity of PAS-GO reached to 100% because at higher pH, the effect of protonation becomes weak and negatively-charged hydroxyl and carboxylic acid functional groups leads higher Pb(II) ions adsorption. PAS-GO may be the best adsorbent for the removal of Pb(II) ions from acidic media (pH 4.0–7.0) because these ions get precipitated in basic media [189,190].
Langmuir, Freundlich, and Dubinin-Redushkevich adsorption isotherms were used to explain the adsorption mechanism of Pb(II) ions onto the surface of PAS-GO adsorbent. Langmuir and Freundlich isotherms are applicable for homogenous and heterogeneous surface adsorption respectively. Calculated results from adsorption isotherms revealed that the adsorption fitted well to Langmuir isotherm with a correlation coefficient (R2) values of 0.9996, 0.9989 and 0.9874 at 293 K, 303 K and 313 K, respectively. Highest correlation coefficient and better fitted Langmuir isotherms confirmed the homogenous adsorption with all the adsorption sites of equal adsorption affinity. Maximum adsorption capacity increased from 200.00 mg/g to 344.80 mg/g as the temperature increased from 293 K to 313 K indicating endothermic adsorption process.
Xu et al. reported the one step synthesis of polyacrylamide-grafted graphene (PAM-GO) composites via in situ radical polymerization by 300 kGy doses γ-ray irradiation of the acrylamide monomer in an aqueous solution at room temperature, leading to GO single layer exfoliation into the PAM polymer [197]. The resulted PAM-GO adsorbent showed a 24.2% degree of grafting of PAM onto the graphene surface with a thickness of 2.59 nm that was a more powerful adsorbent for Pb(II) ions adsorption. Disappearance of XRD (X-ray diffraction spectroscopy) sharp peak from 2θ = 10.7° corresponding to 001 plane reflection from the XRD spectrum of PAM-GO indicated the complete exfoliation of GO sheets and intercalation of PAM chains into the GO layers. In the PAM-GO XPS spectrum, C1s peak at 284.4eV binding energy was attributed to the C-C, C=C and C-H bonds and the peak appeared at 288.4eV was correlated with the O=C-N bond of PAM [163,198]. Effect of contact time on the adsorption efficiency for PAM-GO adsorbent was studied for 45 mg/L as Pb(II) ions concentration at pH 6. The adsorption capacity of PAM-GO increased sharply within the first 20 min. and reached at equilibrium within 30 min. The short period of time for higher adsorption capacity highlights potential industrial applications of the PAM-GO adsorbent. Experimental value (440.4 mg/g) calculated from pseudo-second-order kinetic model parameters for Pb(II) ions adsorption was similar to the calculated value (458.7 mg/g). The correlation coefficient (R2= 0.999) obtained from the pseudo-second-order kinetic model suggested that the adsorption process might be controlled by chemical adsorption involving valence forces through the sharing or exchange of electrons between the sorbent and sorbate. Langmuir and Freundlich isotherms comparison were studied for GO and PAM-GO to examine the Pb(II) ions surface adsorption mechanism. The adsorption of Pb(II) for GO and PAM-GO was well fitted with the Langmuir isotherm model and higher R2 value, indicated specific homogeneous adsorption (i.e., with all the adsorption sites of equal adsorbate affinity) on GO and monolayer adsorption on the PAM-GO adsorbent [199,200]. The theoretical adsorption capacity of PAM-GO, determined from the Langmuir isotherm for Pb(II) was 819.67 mg/g, which was 20 times higher than that of the GO nanosheets. Higher adsorption capacity of PAM-GO was attributed due to good water dispersibility and increased oxygen functionalities.
Yang et al. converted the peripheral carboxylic acid functional groups of reduced GO to amino groups using N-hydroxysuccinimide and 1,3-diaminopropane [201]. The free radical polymerization initiator was anchored at the surface of GO sheets and RGO-PAM polymer brushes were synthesized via in situ free radical polymerization of acrylamide. Staudenmaier method was used to prepare GO which includes the treatment of graphite with potassium chlorate in the presence of concentrated nitric and sulfuric acid. After the stipulated period of time, the reaction mixture was added to an excess of water followed by repeatedly washing till the filtrate neutrality. Free radical initiator was attached onto the surface of thermally reduced GO and used to graft PAM resulting RGO-PAM composites. Two FT-IR absorption peaks at 1384 cm−1 and 1446 cm−1 were attributed with the symmetric and asymmetric bending vibrations of methylene groups of an initiator attached onto the surface of reduced GO, respectively. XPS N1s binding energy absorption peak at 399.1 eV indicated that surface grafting of a free radical initiator. Additionally, the absorption peak at 2242 cm−1 also confirmed the grafting of an initiator. Asymmetric C-H stretching vibration at 2925 cm−1 and C=O stretching vibration at 1647 cm−1 were attributed with the grafting of PAM chains. Pb(II) ions were adsorbed onto the surface of RGO-PAM using dialysis and kinetics was studied since it gives deep knowledge insight the adsorption mechanism. Adsorption kinetics for Pb(II) ions adsorption was evaluated using Lagergren pseudo-first order (Equation (1)) and second-order (Equation (2)) modes:
ln ( q e q t ) = lnq e k 1 t
t q t = 1 ( k 2 q e 2 ) + t q e
where qe and qt are the amounts adsorbed in mg/g at equilibrium and after time t in min., respectively; k1 and k2 are the adsorption rate constants for pseudo first- and second-order reactions respectively. The experimental results did not showed a linear fit with the calculated values; however, the t/qt plots showed good agreement with the pseudo second-order kinetics for Pb(II) ions adsorption. The correlation coefficients (R2) for Pb(II) ion adsorption suggested that the pseudo second-order adsorption mechanism was dominant using RGO/PAM adsorbent. To better understand the adsorption mechanism, the Langmuir and Freundlich adsorption isotherms were studied and results are listed in Table 2. The R2 values for Pb(II) ions adsorption indicated that adsorption mechanism is well fitted with Langmuir isotherms and the maximum adsorption capacity of Pb(II) ions with RGO and RGO/PAM were found to be 500 and 1000 mg/g, respectively.
Separation factor calculated from Langmuir isotherms for Pb(II) ions adsorption onto the surface of RGO-PAM was in the range of 0.313-0.901 indicating that the adsorption of Pb(II) ions was favorable and the adsorption capacity was highest as per literature reports [164]. The superior adsorption capacity of the RGO-PAM composite was attributed with the good dispersion of GO in an aqueous medium due to the introduction of highly functionalized PAM polymer. The adsorption capacity of the RGO-PAM composite was 2-3 times higher than the adsorption capacities of RGO and GO. Thermodynamic studies indicated the negative enthalpy changes, which were responsible for the spontaneous and exothermic adsorption of Pb(II) ions at different temperatures.
Yang et al. prepared ternary lignosulfonate-GO-polyaniline (LS-GO-PANI) nanocomposites via an in situ oxidative polymerization of aniline in the presence of lignosulfonate and GO and examined the effect of time, pH of the medium, adsorbent, and adsorbate concentration in an aqueous medium [72]. Scheme 4 represents the possible surface adsorption mechanism for Pb(II) ions from aqueous solution. LS is water soluble and has a large number of functional groups that are supposed to provide good adsorption interactions in the combination of GO and PANI. An air-tight oxidation method was used for GO preparation using sealed stainless steel autoclave [202]. In brief, expandable graphite, KMnO4 and sulfuric acid containing Teflon reactor was placed in stainless steel autoclave and heated at 110 °C for 2 h. Resulted slurry was diluted and treated with H2O2 followed by repeatedly washing with dilute HCl and deionized water. LS-GO-PANI nanocomposite was prepared using suspension of GO, LS and aniline followed by the oxidative polymerization at 0 °C for 24 h using ammonium persulfate as an initiator. Due to enormous active edges and different surface functionalities, GO is compatible with polymer matrix and provide various nucleation sites for PANI chains anchoring. Moreover, π−π interactions also favor surface polymerization of PANI onto the surface of GO [203,204,205]. Due to higher surface area, resulted LS-GO-PANI ternary composite showed higher adsorption capacity (98.1 mg/g) than GO-PANI (85.70 mg/g) and virgin PANI (95.70) for Pb(II) ion adsorption.
Figure 4A represents the adsorption capacity (Q) and adsorptivity (q) effects with adsorption time for 1.6 g/L ternary LS-GO-PANI adsorbent at 200 mg/L Pb(II) ions initial concentration an initial pH of 5.0 at 30 °C. Adsorption capacity and adsorptivity increased rapidly with time and reached 90.70 and 72.50% after 2 h. After 4 h, the adsorption capacity reached 98.30%, which indicates the excellent adsorption capacity of LS-GO-PANI composite as compared with other adsorbents [172,206]. After reaching to saturation, there was a gradual decrease in the adsorption rate, which was correlated with the adsorption and desorption process at equilibrium onto the surface of the adsorbent. Figure 4B represents the effects of pH variation on the adsorption capacity using 1.6 g/L ternary LS-GO-PANI adsorbent and 200 mg/L initial Pb(II) ions concentration. Figure 4B represents the increasing adsorption efficiency of LS-GO-PANI adsorbent with the increasing pH from 2 to 5. When the pH of the medium increased from 2 to 5, the adsorption efficiency of LS-GO-PANI composite ternary adsorbent increased because as the pH increases, the H+ concentration decreases and other functional groups (carboxyl, epoxy, hydroxyl, and amino groups) get ionized, resulting in the higher adsorption for Pb(II) ions and reached to maximum 98.1 mg/g [207]. Hence, pH 5.0 was set for the further studies for Pb(II) ions adsorptions. As shown in Figure 4C adsorption capacity decreased with LS-GO-PANI adsorbent contents while adsorptivity increased. Decreased adsorption capacity was attributed with the decreased surface area exposed to Pb(II) ions when the content of LS-GO-PANI adsorbent increased. Since, increasing adsorbent dosages for Pb(II) ions adsorption found to be invalid, hence, the effect of initial Pb(II) ions concentration was studied at fixed adsorbent dosage. Figure 4D represents the effect of sorbate concentration on the adsorption efficiency of LS-GO-PANI adsorbent. Adsorption efficiency of LS-GO-PANI adsorbent increased with the increased sorbate Pb(II) ions concentration. While adsorptivity initially increased then decreased after 100 mg/g sorbate concentration because on the increasing amount of sorbate there would not be enough adsorbent content to adsorb Pb(II) ions from the solution as LS-GO-PANI adsorbent gets saturation before 100% adsorption capacity. For Pb(II) ions adsorption, Langmuir adsorption isotherm was fitted well with higher coefficients of 0.9916. Langmuir isotherms were correlated with the homogenous intermolecular forces between the sorbate and equally charged active sites of the adsorbent [172]. Higher adsorption capacity were attributed with the high surface area and large number of active functionalities which provided numerous nucleation sites for PANI growth and enhanced the surface for Pb(II) ions adsorption.

2.3. Removal of Lead using GO-Magnetite’s

Magnetitie’s are the new class of materials which have drawn much attention in the current era specially in the wastewater treatment as the preparation of magnetite’s is very simple and they can be easily separated using magnetic forces. Magnetite’s are being widely used due to their low toxicity, environment friendly, and high adsorption ability [122,208]. Nickel ferrite based reduced graphene oxide (NFRGO) nanocomposite was reported by Lingamdinne et al. to optimized the independent variables viz. adsorbent dosage, solute concentration, and residence time for the removal of heavy metal Pb(II) ions from aqueous solution [209]. Ferrite’s can be easily separated using external magnetic field and can be reused without any structural changes several times. Graphene based magnetite’s not only separated/ recovered easily but also shows higher absorption capacity [208,210,211]. For the preparation of NFRGO, hydrazine hydrate was added to the GO dispersion as prepared by Hummer’s method [212,213]. At pH ≥ 12 nickel nitrate and ferric nitrate solutions in 1:2 molar ratio were added to the above solution in an inert atmosphere and the solution was stirred for 5 h at 120 °C (Scheme 5). Resulted black precipitate was cooled to room temperature and repeatedly washed with deionized water and ethanol to remove the impurities. NFRGO was separated by external magnate and dried under vacuum for 24 at 60 °C. As prepared NFRGO was characterized using XRD, XPS, and Raman spectroscopy. XRD peaks at 2θ = 18.28° and 40° were observed with correspond to RGO [214,215]. Presence of 2θ at 30.43°, 35.60°, 43.26°, 57.32° and 62.70° confirmed the formation of spinel nickel ferrite onto GO surface [216,217]. Shifting of XPS peaks from 532.4 eV to lower range at 530.3 eV confirmed the reduction of GO to RGO. Additionally, the presence of O (1s) at 530.3, Fe (2P) at 711.00 eV and Ni (2P) at 855.00 eV peaks confirmed the formation of NFRGO. In Raman spectrum, G band stands for first-order scattering of E2g mode for sp2 carbon atoms whereas D band is correspond with the vibrations of sp3 carbon atoms. Shifting of D band from 1358 cm−1 to 1303 cm−1 and G band from 1606 cm−1 to lower shift at 1591 cm−1 indicated the reduction of GO. Enhanced intensity ratio (ID/IG) from 0.96 (GO) to 1.094 (NFRGO) confirmed the reduction of GO. 167.26 m2/g surface area was measured using Brunauer-Emmett and Teller (BET) method. Pore volume, 0.24 cm3/g and 5.59 nm pore diameter indicated the formation of meso-porous nano-crystalline NFRGO composite adsorbent.
Adsorption experiments were optimized using different independent variables such as adsorbent dosage, solute concentration and residence time and average values were considered for further studies. All these factors had an interactive consequence when used in combinations. For example, on increasing adsorbent dosage from 250 mg/L to 550 mg/L, a significant enhancement in adsorption efficiency from 80 to 90% was observed whereas adsorption efficiency decreased on increasing the initial solution concentration. Trend was correlated with the accessibility of more vacant active sites due to increased surface area. Reduction in ions removal efficiency was observed on increasing solution concentration with the saturation of active sites of adsorbent whereas there was no significant effect of adsorbent’s residual time. On increasing the adsorbent dosage from 250 mg/L to 550 mg/L, there was a significant enhancement in Pb(II) ions removal efficiency from 87 to 98%. No significant increase on further adsorbent dosage increasing was correlated with the dominance of the repulsive forces in the functional groups. Comparative results of three variables viz. adsorbent dosage, residual time and solution concentration have been depicted in Figure 5. Based on the results of experimental runs, independent variables 18.38 mg/L initial solution concentration, 550 mg/L adsorbent dosage and 83 min adsorbent residual time were optimized which not only may be helpful to reduce the cost of operating treatment process of an industry but also may also reduce the time in achieving the desired performance.
Zhang et al. reported the preparation of magnetic cobalt ferrite-reduced graphene oxide (CoFe2O4-rGO) nanocomposite to absorb the Pb(II) ions from aqueous solution [218]. CoFe2O4-rGO nanocomposite was prepared as reported in literature and used for metal ions adsorption [219,220]. In brief, iron(III) nitrate and cobalt (III) nitrate solutions were drop wise added to the ultrasonicated GO suspension under vigorous stirring. pH 12 was adjusted using 5% NaOH aqueous solution and hydrazine hydrate solution was added slowly to GO suspension. Reaction mixture was stirred for 5 h at 80 °C and cooled to room temperature. Purification was carried out using magnet followed by repeatedly washing with deionized water and absolute ethanol and dried at 50 °C for 24 h under vacuum. CoFe2O4-rGO was characterized with the help of XRD where the CoFe2O4 nanoparticles were found in correspondent with the previous report and the presence of XRD peak 2θ at 26.5° confirmed that CoFe2O4-rGO was well crystallized. Low zeta potential indicated the availability of entire negatively-charged functional groups environment from pH 4 to 10 for the better adsorption of heavy metal ions and CoFe2O4-rGO was found to be well dispersed in water pertaining a black suspension in aqueous solution.
Adsorption analysis involved the use of different dosage of CoFe2O4-rGO adsorbent and 8 mg/L was optimized to study the Pb(II) ions adsorption at various pH from lead (II) nitrate solution (20 g/L). From the results, it is clear that the adsorption of Pb(II) ions was very sensitive to pH variations. At low pH, low adsorption efficiency was attributed due to the increased repulsive forces between the positively-charged functional groups of adsorbent and positively-charged Pb(II) ions and the precipitation of Pb(II) ions as [Pb(OH)], [Pb(OH)2], [Pb(OH)3], [Pb3(OH)4]2+ [Pb2(OH)]2+ [Pb6(OH)8]4+, and [Pb4(OH)4]4+ [164,221,222]. Increase adsorption efficiency over pH 4 was attributed with the increased attractive forces between the positively-charged functional groups of adsorbent and positively-charged Pb(II) ions and was found to be highest as 87% at 5.3 pH. The adsorption kinetics was analyzed using pseudo-first and second-order kinetic models. The adsorption of Pb(II) ions by CoFe2O4-rGO reached equilibrium in 80 min. Pseudo-second order model was found to be well fitted with the R2 value of 0.9934 suggesting chemisorption adsorption process and the calculated value was found to be 122.2 mg/g. Adsorption isotherms were analyzed using Langmuir and Freundlich equations. Langmuir isotherms were found to be well fitted with the experimental data which indicated the monolayers adsorption of Pb(II) ions onto the surface of CoFe2O4-rGO adsorbent.
Fan et al. prepared magnetic ternary composites of chitosan, Fe3O4, and GO for the effective and selective removal of Pb(II) ions from aqueous solution [223]. To ultrasonicated GO solution, reagents 1-ethyl-3(3-hydroxyethylaminoprophy) carbondiimide hydrochloride and N-hydroxylsuccinimimde were added at pH to activate carboxylic functionalities of GO. Magnetic chitosan and activated GO was suspended using ultrasonication for 10 min and stirred for 2 h at 60 °C. The precipitate was washed with NaOH and then with water repeatedly until the pH 7 was obtained. MCGO product was collected using magnet and dried under vacuum at 50 °C. The magnetic fluid was coated onto chitosan to accelerate the separation through an improved surface area and reduce the dose requirement for the adsorption of Pb(II) ions. The adsorption amounts and adsorption rates were calculated from the concentration difference of the solution used before and after the adsorption process using following equations:
Q = ( C 0 C e ) V W
E = C 0 C 0 C 0   x   100 %
where C0 and Ce are the initial and the equilibrium concentrations of metal ions in mL/L, respectively; W is the amount of an adsorbent used, in grams; and V is the volume of metal ion solution in liter. Since, the adsorption is very sensitive to pH variations, adsorption capacity of MCGO was determined at varying pH from 1.0 to 7.0. At low pH, excessive competitive H+ ions concentration inhibits the adsorption of Pb(II) ions and usually adsorption of heavy metal ions do not occur at low pH. Pb(II) ions adsorption capacity increased with the increasing pH from 1-5 and was measured 50.23 mg/g at pH 5. In acidic media, the slight decrease in uptake was attributed to amino group protonation, which may hinder complex formation.
Pb(II) ions adsorption onto MCGO was obtained maximum within first 30 min. and no significant alteration was observed after 1 h which indicated that optimum adsorption time for Pb(II) ions. The initial higher sorption within 60 min. was attributed to high surface reactivity of MCGO due to sufficient number of exposed active sites followed by the large surface area, which decreased later on due to a decrease in the number of bonding sites on the surface of the adsorbent and aggregation between particulates. Langmuir and Freundlich isotherms are the fundamental and most frequently used adsorption isotherms to describe the adsorption phenomenon and behavior of metal ions onto the surfaces. The maximum adsorption capacity of MCGO determined from the Langmuir isotherm was found to be 82.10 mg/g, which was almost similar with the calculated value of 76.94 mg/g for monolayer chelation adsorption. Higher adsorption capacity for Pb(II) ions when compared with other adsorbents were attributed with the additional interactions of axial hydroxyl and amino functional groups with metal ions. For the possibility of regeneration and reusability of MCGO, experimentally desorption efficiency was found to be 90.3% and 90.1% at pH 1 and 2, respectively, indicating that adsorbed metal ions could be removed efficiently by desorption from the adsorbent surface. Adsorption percentage almost remained steady in the first four regeneration cycles and then decreased to 75% after fifth regeneration cycles. Hence, regeneration and reusability indicated that biodegradable and biocompatible MCGO has long term stability for the adsorption of Pb(II) ions.
A composite of hydrated manganese oxide and GO (HMO-GO) with excellent settling ability (<2 min) was fabricated by in-situ growth of nanosized hydrated manganese oxide (HMO) onto the GO nanosheet surface [224]. Typically, GO was suspended into MnCl2 solution at pH 7 for 24 h at room temperature followed by centrifugation to obtained Mn(II)-GO which was further added to NaClO-NaOH solution at the alkalinity of 5% and active chlorine of 6%. The mixed solution was stirred for 24 h to oxidize Mn(II) to Mn(IV). Finally, the solution was centrifuged and solid was repeatedly washed with HCl and deionized water untill neutral pH and freeze dried under vacuum. HMO grafted GO i.e., HMO-GO adsorbent substructure revealed that electron dense single grain HMO nanoparticles were uniformly distributed onto the GO surface. To increase the oxygenated abundance onto the GO surface, polymer or surfactants as stabilizers were dispersed using similar approaches [175,225]. Adsorption behavior of HMO-GO composite and GO as an adsorbent were compared at pH from 2.5 to 6.7. The adsorption capacity of HMO-GO and GO increased with increasing pH of the medium because at higher pH, deprotonation increases, which results more negative active sites to adsorb positively-charged Pd(II) ions. A sharp decrease in adsorption capacity in strong acidic media indicated the regeneration possibilities of HMO-GO adsorbent for reuse. The leaching of Mn from HMO-GO was negligible during the adsorption experiment over the entire pH range.
Selective adsorption of Pb(II) ions in presence of Ca(II) and Mg(II) co-existing ubiquitous versatile alkaline earth metal cations onto the surface of HMO-GO was compared with that of GO. Presence of Ca(II) and Mg(II) cations (concentration of Ca(II), Mg(II)/ Pb(II) = 50) do not affected the selective adsorption of Pb(II) ions by HMO-GO adsorbent whereas a significant reduction in the adsorption capacity of GO was observed. Selective Pb(II) ions adsorption by HMO-GO was attributed with the specific, complex adsorption process by nanostructured homogenous distribution HMO onto the surface of GO [226]. Reduced desorption of Pb(II) ions onto GO was attributed with the nonspecific, electrostatic attraction of oxygenated functional groups and greatly affected due to the presence of Ca(II) and Mg(II) cations.
Due to lower Δ G hydration 0 (Ca(II) = −1656 kJ/mol, than Mg(II) = −2049 kJ/mol) and greater ion exchange ability, Ca(II) had greater influenced on the adsorption of Pb(II) ions onto GO surface [227]. Higher distribution coefficient of HMO-GO further indicated the selective adsorption of Pb(II) ions which slightly influenced due to humic acid presence which forms strong complexes with Pb(II) ions or other heavy metal ions by π−π interactions [67]. A 3-4 time higher Pb(II) ion adsorption by HMO-GO than GO and bulky HMO in presence of 500 mg/L Ca(II) was attributed with the homogenously distributed nanosized HMO. The HMO-GO and GO adsorption isotherms for Pb(II) at pH 5 in the absence and presence of Ca(II) were investigated using the Freundlich and the Langmuir models. The higher correlation coefficients of the Freundlich model than the Langmuir model for HMO-GO suggested a heterogeneous chemisorption process through inner-sphere complexation, whereas, opposite results were obtained for GO, suggesting monolayer adsorption on the surface through simple ion exchange method. The experimentally obtained sorption capacity of Pb(II) for HMO-GO was 553.6 mg/g, which was higher than that observed for any other Mn-based adsorbent [224].

3. Conclusions and future perspective

Graphene based nanoadsorbents have been proven to play the vital role in the selective adsorption of heavy metal ions, such as Pb(II), from wastewater. The selective recovery and reuse of valuable adsorbents and pollutants are the important challenges for the adsorption technology using nanoadsorbents with favorable structures, morphology, superior adsorption capacities, and ease of separation. Graphene is always thanked for its unique property of functionalization, used to alter its properties and, consequently, its applications. This review exploited recently-developed graphene-based novel nanoadsorbents for the effective and selective removal of Pb(II) ions from wastewaters. In addition to the various own functionalities, GO was further surface modified with the negatively-charged functional groups to enhance the selective and effective Pb(II) ion adsorption from wastewaters. Due to wide varieties of surface functional groups, high surface area, and a preponderance of exposed edges planes, GO exhibited remarkable superior adsorption of Pb(II) ions. In addition, GO composites with ion scavengers (for example, EDTA), metal nanoparticles, magnetites, polymers, and aerogels have been reviewed for the adsorption of Pb(II) ions under the influence of temperature, pH of the medium, adsorbate, and sorbent loadings, etc., and exhibited superior adsorption than pristine GO for Pb(II) ion adsorption from an aqueous solution. One of the major advantages revealed by the graphene-based nanoadsorbents is the recovery of adsorbents and adsorbates even after a series of life cycles. Although simple and effective routes for GO-based nanoadsorbents with high surface area and pore size for superior adsorption of heavy metal ions are still in demand, graphene-based nanoadsorbents have proven their potential adsorbability for the expediency of mankind and the environment.

Author Contributions

S.H.H., M.K. put forwarded the idea and prepared the manuscript. J.S.C. and S.H.H. has edited and approved the manuscript.

Funding

This study was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by The Ministry of Science, ICT and Future Planning (2019R1A2B5B02069683).

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Heavy metal ions adsorption on EDTA-GO adduct surface [164].
Figure 1. Heavy metal ions adsorption on EDTA-GO adduct surface [164].
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Scheme 1. Adsorption of (Pb)II ions based on ion-exchange process [164].
Scheme 1. Adsorption of (Pb)II ions based on ion-exchange process [164].
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Scheme 2. Adsorption of Pb(II) ions involving complex forming of EDTA with Pb(II) [164].
Scheme 2. Adsorption of Pb(II) ions involving complex forming of EDTA with Pb(II) [164].
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Figure 2. (a) Adsorption efficiency of LDH, GO, pRGO, and x Mg−Al LDH/pRGO adsorbents at pH 1 to 10. (b) Speciation of Pb(II) as a function of pH [174].
Figure 2. (a) Adsorption efficiency of LDH, GO, pRGO, and x Mg−Al LDH/pRGO adsorbents at pH 1 to 10. (b) Speciation of Pb(II) as a function of pH [174].
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Scheme 3. Preparation of NGAs and electrosorption of Pb(II) ions [180].
Scheme 3. Preparation of NGAs and electrosorption of Pb(II) ions [180].
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Figure 3. PAS-GO, AS-GO, and GO Langmuir isotherms for Pb(II) adsorption in aqueous solution at 303 K [193].
Figure 3. PAS-GO, AS-GO, and GO Langmuir isotherms for Pb(II) adsorption in aqueous solution at 303 K [193].
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Scheme 4. Possible Pb(II) ion adsorption with LS-GO-PANI ternary composite adsorbent [72].
Scheme 4. Possible Pb(II) ion adsorption with LS-GO-PANI ternary composite adsorbent [72].
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Figure 4. (A) Effect of contact time vs. adsorption capacity and adsorptivity of LS-GO-PANI adsorbent, (B) effect of pH on Pb(II) ions adsorption, (C) effect of adsorbent concentration at 200 mg/L initial Pb(II) ions concentration, and (D) effect of Pb(II) ions concentration [72].
Figure 4. (A) Effect of contact time vs. adsorption capacity and adsorptivity of LS-GO-PANI adsorbent, (B) effect of pH on Pb(II) ions adsorption, (C) effect of adsorbent concentration at 200 mg/L initial Pb(II) ions concentration, and (D) effect of Pb(II) ions concentration [72].
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Scheme 5. Schematic representation of NFRGO preparation [209].
Scheme 5. Schematic representation of NFRGO preparation [209].
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Figure 5. Cubic representation of independent variables response [209].
Figure 5. Cubic representation of independent variables response [209].
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Table
Table 1. Techniques characteristics used for Pb(II) removal.
Table 1. Techniques characteristics used for Pb(II) removal.
TechniquesMaterials usedAdvantagesDisadvantagesRef.
Adsorption Natural adsorbents, Carbon based hybrid adsorbents such as carbon nanotubes, graphene, activated carbon etc.Simple, cost effective, efficient, reversible, environment friendly.Expensive, low selectivity, time consuming, difficult sludge separation etc.[47,72,73]
Solvent ExtractionExtractants, such as sodium succinate, lauryl ammonium compounds etc.Efficient at higher concentration, better recovery of metals etc. Complex, require continuous energy consumption, need chemicals, inappropriate efficiency etc.[74,75]
Ion Exchange Organic-inorganic or hybrid ion exchanger as –SO3H and –COOH based resin, salicylic-melamine-formaldehyde resin etc.Simple operation, high treatment capacity, high efficiency, fast kinetics, able to clean up to ppb level etc.Expensive, need diluted medium, highly sensitive to pH changes, difficult resin regeneration etc.[18,76,77,78]
Membrane FiltrationPolymer, carbon-based materials embedded into polymers/ ceramics lead-imprinted materials, etc. are used for membrane preparationNo use of chemicals, ease of operation, hybrid membranes combines separation and adsorption etc.Expensive, susceptible to fouling, continuous energy consumption, high pressure, need diluted medium, Low level of water permeation.[79,80,81,82,83,84,85,86,87]
Chemical PrecipitationPrecipitating agents as lime, pyrite, sulfides, chelating agents.Efficiently able to clean up to ppm level, selective metal precipitation is possible.Complex, require toxic and corrosive chemicals, cost effective, difficult disposal of sludge, largely effected by pH change, nonselective,[9,88,89,90]
Reverse OsmosisSemi-permeable membranes Able to remove most of the pollutants Complex, nonselective, continuous energy input, plug fouling, Low efficiency, Slow removal rate.[91]
Electro-chemicalSpecific electrode materials, hybrid electrodes, coated electrode etc. Highly specific, able to remove suspended solids, dissolved metals. High cost electrode required, need continuous energy input, higher cost, highly sensitive to pH changes.[92,93,94,95]
Table
Table 2. Langmuir and Freundlich adsorption results for Pb(II) onto the surface of RGO and RGO/PAM composite [201].
Table 2. Langmuir and Freundlich adsorption results for Pb(II) onto the surface of RGO and RGO/PAM composite [201].
Langmuir ModelFreundlich Model
Adsorbentsqm(mg/g)KL (L/mg)R2RSDKF ((mg1-nLn)/g)nR2RSD
RGO5000.001490.9890.019613.141.840.9600.013
PAM/GO10000.001370.9870.01737.421.880.9500.011

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Kumar, M.; Chung, J.S.; Hur, S.H. Graphene Composites for Lead Ions Removal from Aqueous Solutions. Appl. Sci. 2019, 9, 2925. https://doi.org/10.3390/app9142925

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Kumar M, Chung JS, Hur SH. Graphene Composites for Lead Ions Removal from Aqueous Solutions. Applied Sciences. 2019; 9(14):2925. https://doi.org/10.3390/app9142925

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Kumar, Mukesh, Jin Suk Chung, and Seung Hyun Hur. 2019. "Graphene Composites for Lead Ions Removal from Aqueous Solutions" Applied Sciences 9, no. 14: 2925. https://doi.org/10.3390/app9142925

APA Style

Kumar, M., Chung, J. S., & Hur, S. H. (2019). Graphene Composites for Lead Ions Removal from Aqueous Solutions. Applied Sciences, 9(14), 2925. https://doi.org/10.3390/app9142925

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