Abstract
Microplastics (MPs), act as vectors of heavy metal pollutants in the environment, is of practical significance to study the adsorption process and mechanism on heavy metals. In this study, polystyrene microplastics (PSMPs) were used as model MPs to study the adsorption of Pb2+ on PSMPs and the effects of humic acid (HA) on the adsorption process. The results showed that HA promoted the adsorption of Pb2+ on PSMPs, and the higher the concentration of HA, the greater the adsorption of Pb2+. With the increase of pH value and decrease of ionic strength, the adsorption capacity of PSMPs for Pb2+ increased. The scanning electron microscope equipped with the energy dispersive spectroscope (SEM–EDS), fourier transform-infrared spectra (FT-IR) and X-ray photoelectron spectroscopy (XPS) analysis showed that Pb2+ could be adsorbed directly onto PSMPs and also indirectly by HA. The higher KSV values in the PSMPs-HA-Pb2+ system than PSMPs-HA system by fluorescence analysis of HA suggested that HA acted as a bridging role in the adsorption of Pb2+ on PSMPs. The site energy distribution analysis further revealed that HA increased the average site energy μ(E*) and its standard deviation σe* of PSMPs by introducing more adsorption sites, thus enhanced the adsorption affinity of PSMPs. This study provided more thoughts and insights into the adsorption behavior and mechanism of MPs for Pb2+ in aquatic environments.
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Introduction
Microplastics (MPs) are defined as plastic fragments or particles with size less than 5 mm by the National Oceanic and Atmospheric Administration1. MPs consist of plastic microbeads released directly into the environment (primary sources) and plastic fragments derived from the degradation of large plastics (secondary sources) due to weathering processes (e.g. UV photodegradation, mechanical abrasion, biodegradation, etc.)2. Degradation processes of plastics are extremely slow, and thus MPs potentially persist for a long time periods in the environment, where degradation may last for decades3,4. In addition, MPs are easily driven by wind and water currents, gaining the ability of long-distance diffusion and migration to reach different regions, thus widely distributed in aquatic environment such as surface runoff, rivers, lakes and oceans5,6. MPs can accumulate in organisms through the food chains and cause many adverse effects on aquatic and terrestrial organisms, including inhibition of growth and development, endocrine disruption, and immunity and neurotransmission dysfunction7,8,9.
With the characteristics of small size and large specific surface area, MPs always act as carriers to accumulate and transport heavy metal pollutant, and may cause the bioaccumulation of contaminations and toxicants in aquatic environments10,11. In recent years, the adsorption properties and mechanisms of heavy metals onto MPs have attracted the attention and research of scientists12,13,14,15. Holmes et al.12 investigated the rates and mechanisms of trace metals (Cr3+, Co2+, Ni2+, Cu2+, Zn2+, Cd2+ and Pb2+) binding to virgin and beached polyethylene (PE) pellets, and found that plastics represented an important vehicle for the transport of metals in the marine environment. Gao et al.13 observed the significant differences in the effects of different plastic types and locations on the adsorption of different MPs for Pb2+, Cu2+ and Cd2+.
Pb2+ is one of the most representative heavy metal pollutants owing to its persistence, bioaccumulation and toxicity in the environment16. As a highly toxic metal, Pb2+ will affect the morphology, physiology and life activities of animals, plants as well as human beings when it accumulates in living organisms17,18,19,20. The environmental behavior of Pb2+ is affected by MPs contaminants. The interaction between MPs and Pb2+ under coexistence conditions not only increases the toxicity of MPs themselves, but also expands the contamination range of Pb2+ through the diffusion ability of MPs. Therefore, it is necessary to study the Pb2+ adsorption process and mechanism on MPs. Previous studies have showed that MPs can adsorb Pb2+ in aquatic environment, and the interaction between MPs and Pb2+ is affected by different environmental conditions such as dissolved organic matter (DOM), pH value, ionic strength, temperature and other conditions13,21,22,23,24. Zou et al.21 found that pH can significantly affect the adsorption of Pb2+ on chlorinated polyethylene (CPE), polyvinyl chloride (PVC) and polyethylene (PE), but ionic strength exerted a relatively slight effect on this process. Ahechti et al.23 found that the adsorption capacity of polyethylene (PE) and polypropylene (PP) for Pb2+ was affected by the physicochemical conditions of the aquatic environment (exposure time, pH and salinity). Godoy et al.24 investigated the adsorption of Pb2+ by five different types of MPs in Milli-Q water and natural waters, and found that an enhancement of metal adsorption in waters with high concentration of DOM. HA, a representative DOM and widely exists in the aqueous environment, is an important natural ligands in regulating the speciation, bioavailability and ultimate fate of trace metal element in the environment25,26. HA contains a large number of oxygen-containing functional groups such as carboxyl (–COOH) and hydroxyl groups (–OH), which will interact with Pb2+27. Our previous study has shown that HA can be adsorbed on PSMPs in the aquatic environment through hydrophobic interaction and π−π electron donor acceptor interaction28. Li et al.29 found that HA promoted the adsorption of Cd2+ on polyvinyl chloride (PVC) and polystyrene (PS) MPs. In addition, it has also been shown that HA increased the adsorption amount of Pb2+ on other carbon materials such as activated charcoal particles30. These studies suggested that HA could affect the adsorption performance of Pb2+ on MPs. However, there were few studies on this relevant mechanism, and more in-depth studies were needed.
In this study, PSMPs were used as model MPs31 to study the interaction of Pb2+ with PSMPs and the effects of HA on the adsorption process. Adsorption kinetic and isotherm were conducted at different condition (HA concentration, pH value and ionic strength) to research the adsorption characteristic of Pb2+ adsorption. The surface morphology of PSMPs before and after adsorption was analyzed using SEM–EDS, and FT-IR as well as XPS were used to study the binding mechanism of PSMPs with Pb2+ and HA. In addition, the effect of HA on the adsorption of PSMPs for Pb2+ was investigated using fluorescence quenching analysis of HA and site energy distribution theory. The results helped to further understand the characteristics and mechanism of Pb2+ adsorption onto MPs, and provide more information for the evaluation of environmental behavior and toxicological effects of MPs in aquatic environments.
Materials and methods
Materials and chemicals
Polystyrene microplastics (PSMPs) and Aldrich Humic Acid (HA, sodium salt) were purchased from Sigma-Aldrich (St. Louis, MO, USA). The characteristics of PSMPs were reported in our previous study31. Lead nitrate (Pb(NO3)2), sodium nitrate (NaNO3), calcium nitrate (Ca(NO3)2), nitric acid (HNO3) and sodium hydroxide (NaOH) were obtained from Guangzhou Chemical Reagent Co., LTD. (Guangzhou, China). All chemicals were of A.R. grade.
Sample preparation
The PSMPs were prepared into 50.0 mg/L suspension with ultrapure water (18.2 MΩ). HA solution, obtained by dissolving HA sodium salt in 0.10 mol/L NaOH solution and stirred overnight at 27.0 ± 0.1 ℃, was adjusted to pH 7.0 and then filtered through 0.45-μm cellulose acetate filter paper (Millipore, Billerica, MA, USA). The filtrate was dialyzed with a dialysis membrane (500 D) and finally stored at ~ 4.0 ℃ in the dark. The relevant characterization of HA was shown in the Supplementary data. Pb2+ stock solution (500 mg/L) was obtained by dissolving a quantity of Pb(NO3)2 in distilled water. All the solution pH was adjusted using 0.10 mol/L HNO3 or 0.10 mol/L NaOH and measured by an Orion pH/ISE meter (Model 710 A, Thermo Fisher Scientific). The ionic strength was adjusted by adding NaNO3 or Ca(NO3)2 solution, respectively.
Adsorption experiments
Batch adsorption experiments were employed as described previously with minor modifications28. The adsorption kinetic experiments of Pb2+ uptake on PSMPs were carried out by adding PSMPs suspension, Pb2+ stock solution and HA solution into 500 mL conical flask. The initial Pb2+ concentration was 5.00 mg/L and the HA concentrations were 0.00, 1.00, 2.50, 5.00 mg·C/L, respectively. Experimental HA concentrations were determined based on HA concentrations in natural waters ranging from 1 to 10 mg/L32. The suspensions were equilibrated on a reciprocating shaker (Shanghai Tensuc Ltd., China) at 27.0 ± 0.1 °C (room temperature) in the dark and sampled at different time within 0–4.0 h. For the adsorption isotherm experiment, the initial Pb2+ concentration was 0.50–15.0 mg/L, and the equilibrium time was set at 4.0 h based on preliminary kinetic experiments results. The experiment pH value was adjusted to 3.0 and 6.0 using 0.10 mol/L HNO3 or 0.10 mol/L NaOH, and the ionic strength was set to 0.01, 1.00 and 10.0 mmol/L for NaNO3, and 0.03, 0.33 and 3.33 mmol/L for Ca(NO3)2. Pb2+ was the predominant form present in the solution33. After the experiment, the suspensions were collected and filtered with a 0.45-μm filter membrane, and part of the filtrate is used for Pb2+ concentration determination with AAS (Z-2000, Hitachi, Japan), while the other part is used for HA fluorescence detection (RF-5301PC, Shimadzu, Japan). The adsorption amounts of Pb2+ adsorbed on PSMPs were calculated from the differences between the initial and final Pb2+ concentrations in solutions; mass losses for control samples were negligible (< 1%).
The adsorption process of Pb2+ on HA was described in Supplementary data.
The experiments for each condition were performed in triplicate and took the average.
Analytical method
The zeta potential of PSMPs at different background ionic conditions (Na+ or Ca2+) were analyzed by Zeta potential analyzer (BI-PALS, Brookhaven, American) at the range of pH 2.0–10.0. The elemental analysis (C, H, N, O, S) of HA was characterized using Elemental analyzer (Vario EL cube, Elementar, Germany). The concentration of HA was measured by TOC analyzer (TOC-L CPH, Shimadzu, Japan). The determation of functional groups (carboxyl and hydroxyl) of HA were performed following the method of Ma et al.34. Fluorescence excitation (Ex)-emission (Em) matrix (EEM) spectra of HA was measured at Em wavelength 350–600 nm and Ex wavelength 220–550 nm using a fluorescence spectrometer (RF-5301PC, Shimadzu, Japan). The increments of Em and Ex wavelengths were 1 and 5 nm, and slit bandwidths were settled at 5 nm. The surface morphology and elemental composition of PSMPs were determined using the scanning electron microscope with SEM–EDS (Hitachi U8010, Hitachi, Japan). The functional groups of PSMPs before and after adsorption were characterized using FT-IR (PerkinElmer frontier, American). The FT-IR spectrum was obtained in the wavelength of 400–4000 cm−1 with a 1 cm−1 resolution. XPS (Thermo Scientific K-Alpha, American) was used to characterize the surface elemental compositions, and the measurement was conducted by using an Al Kα X-ray source at pass energy of 50 eV (for highresolution spectra) and 150 eV (for survey spectra).
Details of the data analysis for Pb2+ adsorption onto PSMPs are given in the Supplementary data, and data analysis was performed with Origin Pro 9.0 and MATLAB 2021b for windows.
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Results and discussion
HA-dependent adsorption of Pb2+ onto PSMPs
Effect of different HA concentration on Pb2+ adsorption onto PSMPs
The adsorption kinetic of Pb2+ onto PSMPs at different initial HA concentrations were investigated. As shown in Supplementary Figs. S1 and S2, the adsorption kinetics of Pb2+ onto PSMPs with HA were similar to those without HA under different conditions. The adsorption amount of Pb2+ was very quick initially and almost completed in the first 60 min, then the Qt increased quite slowly in 60 ~ 240 min as the contact time increased, and finally reached equilibrium14. Consequently, a contact time of 240 min was selected for the following experiments, which was sufficient for the adsorption of Pb2+. To further clarify the adsorption kinetics of Pb2+ onto PSMPs, pseudo-first-order and pseudo-second-order kinetic models were utilized to fit the experiment data, with the specific fitted parameters shown in Supplementary Tables S1 and S2. The higher R2 values of pseudo-second-order model showed that this model fitted the experimental data better than pseudo-second-order kinetic model. The results also indicated that the chemical adsorption might be the rate-limiting step of Pb2+ adsorption mechanism6,35. The presence of HA increased the adsorption amount of Pb2+ on PSMPs, and the equilibrium absorption capacity Qe increased with the increase of HA concentration.
The adsorption isotherm curves of Pb2+ onto PSMPs in the absence and presence of HA were shown in Supplementary Figs. S3 and S4. In order to analyze adsorption characteristic, the Langmuir and Freundlich isotherm models were used to fit the adsorption data, respectively, and the fitting parameters were listed in Supplementary Tables S3 and S4. The higher R2 values of Langmuir model than Freundlich model suggested that Langmuir model could be better employed for characterizing equilibrium adsorption of Pb2+ on PSMPs with/without addition of HA, indicating that the chemisorption and monolayer adsorption played a significant role in the Pb2+ adsorption15,36. As showed in Fig. 1, KL and Qm increased accordingly with the increase of HA concentration, indicating that the existence of HA promoted the adsorption affinity and capacity of PSMPs for Pb2+. For example, the adsorption amount of Pb2+ on PSMPs increased from 0.443 to 2.13 mg/g when the HA concentrations were 0.00–5.00 mg·C/L, with the condition of pH 6.0 and 0.10 mmol/L NaNO3. The results were similar to other heavy metal adsorption in previous studies29,37. Li et al.29 found that the HA affected the adsorption of Cd2+ on PS and PVC MPs. Yang et al.37 demonstrated that the presence of HA was beneficial to the adsorption of few-layer reduced graphene oxide (FRGO) and few-layer graphene oxide (FGO) for Cu2+.
The promotion effect of HA on the adsorption of Pb2+ to PSMPs was presumed to be because HA played an indirect role as a bridge in the adsorption process. In order to study the specific influence process of HA, the adsorption of HA on PSMPs and the adsorption of Pb2+ on HA were discussed below. Our previously reported works28 had researched the interaction between PSMPs and HA, and it showed that the adsorption of HA on PSMPs conformed to pseudo-second-order kinetic model and Freundlich model. HA adsorbed on PSMPs surface through hydrophobic and π−π interaction (aromatic structure). The adsorption experiments of Pb2+ on HA were conducted and the adsorption kinetic and isotherm curves were shown in Supplementary Figs. S5 and S6, as well as the fitting parameters were shown in Supplementary Tables S5 and S6. The pseudo-second-order kinetic model and Langmuir model could be used to describe the adsorption characteristics of Pb2+ on HA well. Researches had shown that Pb2+ combined with carboxyl and hydroxyl groups in HA molecule to form stable compounds through complexation, ion exchange and electrostatic interaction38,39. The results of elemental analysis and group determination of HA also showed that HA had hydroxyl and carboxyl groups (Supplementary Table S7), which was similar to others works40.
Comparing the adsorption kinetic results (Supplementary Figs. S1, S2 and S5), the adsorption equilibrium time of Pb2+ on HA was shorter than that on PSMPs, illustrating that Pb2+ preferentially adsorbed on HA to achieve adsorption equilibrium in PSMPs-HA-Pb2+ system. Then HA-Pb2+ complex adsorbed onto PSMPs through the interaction between HA and PSMPs, leading to the indirect adsorption of Pb2+ onto PSMPs. The higher HA concentration, the more Pb2+ indirectly adsorbed. In addition, free Pb2+ also adsorbed directly onto PSMPs due to electrostatic interaction, until the concentration of Pb2+ in the two phases reached equilibrium.
Effect of Ionic strength on Pb2+ adsorption onto PSMPs in the presence of HA
Ionic strength played an important role in Pb2+ adsorption onto PSMPs in the presence of HA. The Qe and V0 of adsorption kinetic results (Supplementary Tables S1 and S2) as well as KL and Qm of Langmuir model parameters (Fig. 1), decreased with the increase of ionic strength, showing that the higher ionic strength inhibit the adsorption of Pb2+ onto PSMPs. For instence, at pH 6.0 and 5.00 mg·C/L HA, the Qm of Pb2+ decreased from 2.13 to 1.57 mg/g, and from 1.97 to 1.42 mg/g as the concentration of Na+ and Ca2+ increased, showing that the presence of background ions were not favorable for Pb2+ adsorption. Similar results were found in previous studies22,23,33,41.
The pHpzc of PSMPs in different ionic strength condition was shown in Supplementary Fig. S7. With increasing ionic strength, the pHpzc of PSMPs increased, which was because the charge screening effect by positively charged background ions (Na+ or Ca2+)42. What’s more, the effect of Ca2+ on the pHpzc of PSMPs was greater than that of Na+ under the same ionic strength condition, as the charge screening effect of divalent positive ions was stronger than that of monovalent positive ions. When the ionic strength increased, the surface negative charge of PSMPs reduced, which resulted in the weakening of electrostatic interaction between PSMPs and Pb2+. In addition, according to the DLVO theory, increasing the ionic strength of solution compressed the electric double layer and reduced the electrostatic repulsion, resulting in an increase in the aggregation of PSMPs and a decrease in the effective adsorption sites2,31. Competitive adsorption was another reasons for the reduction of Pb2+ adsorption. Background electrolyte ions (Na+ and Ca2+) could compete with Pb2+ for specific available adsorption sites on PSMPs and HA molecules43,44. Although higher ionic strength was conducive to the adsorption of HA on PSMPs28, the effect of high ionic strength condition on the adsorption of Pb2+ was much stronger than that on the adsorption of HA. Therefore, high ionic strength ultimately inhibited the adsorption of Pb2+ on PSMPs.
Effect of pH on Pb2+ adsorption onto PSMPs in the presence of HA
The surface charge of the adsorbent, the structure of HA and the ionic species of metals were influenced by the solution pH value, so that the interaction between different substances during adsorption is related to the pH conditions37. The adsorption of Pb2+ on PSMPs with or without HA at different pH value was studied. As shown in Fig. 1, the Qm of Pb2+ adsorption on PSMPs increased with the increasing solution pH value regardless of the presence of HA. At the condition of 0.10 mmol/L NaNO3 and 5.00 mg·C/L HA, the Qe of Pb2+ increased from 1.94 to 2.13 mg/g when pH value ranged from 3.0 to 6.0, indicating that higher pH values was beneficial for the adsorption of Pb2+ on PSMPs.
The effect of pH on adsorption is related to the surface charge of PSMPs. The zeta potential of PSMPs gradually decreased with the increase of pH in the range of pH 2.0–10.0 (Supplementary Fig. S7). PSMPs was negatively charged and readily attracted positively charged Pb2+ through electrostatic interaction under experimental pH conditions (pH 3.0 and pH 6.0)15. The negative charges of PSMPs increased with increasing pH, which led to a corresponding increase in electrostatic interactions between PSMPs and Pb2+, and enhanced the adsorption capacity of PSMPs6. The decrease in pH also causes competitive adsorption. The large amounts of hydrated hydrogen ions H3O+ present in solution at low pH conditions competed with Pb2+ for adsorption sites on the surface of PSMPs and inhibited the adsorption of Pb2+45,46. Similar trends were reported for the adsorption of metal ions on other MPs as well as some kind of nanomaterials14,36,43.
The addition of HA further increased the role of high pH in promoting the adsorption of Pb2+ onto PSMPs. In the presence of HA, the solution pH not only affected the adsorption capacity of Pb2+ on PSMPs, but also affected the binding characteristics of HA and Pb2+. The adsorption of HA onto PSMPs was little affected by pH, but the adsorption of Pb2+ on HA increased with the increase of pH value. The molecular structure of HA was affected by the pH value of solution, i.e., the stretched linear HA structure gradually curled and became a compacted form as the pH decreased47. Therefore, HA exposed more functional groups under high pH conditions than low pH conditions, which enhancing its binding with Pb2+.
Different spectroscopic analysis in adsorption process
Spectral characterization of PSMPs before and after adsorption
The morphology and microstructure of PSMPs before and after Pb2+ adsorption were characterized using SEM–EDS techniques, and the results were shown in Fig. 2. In the absence of HA, the virgin PSMPs particles had globular features and the surface of PSMPs was smooth (Fig. 2a). Slight unevenness of PSMPs was observed in the presence of HA (Fig. 2c), indicating a small amount of HA molecules distributed on the surface of PSMPs. After the adsorption of Pb2+, the surface of PSMPs remained relatively smooth when the HA was absence (Fig. 2b), while the surface inhomogeneity of PSMPs increased when HA was presence (Fig. 2d), showing that more HA distributed on the surface of PSMPs. The results of EDS analysis showed that the adsorption of Pb2+ onto PSMPs was significantly increased when the HA was presence. The above results showed that, when HA was present, Pb2+ could be adsorbed directly onto PSMPs, and also indirectly onto PSMPs by HA.
To explore the structural variation caused by the interaction between Pb2+, HA and PSMPs, FT-IR spectra was used to determine the changes in functional groups before and after adsorption, and the results were shown in Fig. 3. Obvious characteristic peaks of aromatic substances were observed in virgin PSMPs particle. The prominent peak appeared at 696, 755, 1452, 1493 and 2840–3100 cm−1 were associated with the stretching, deformation and bending vibrations of aromatic ring and aliphatic C–H bonds in PSMPs48. The spectra of PSMPs before and after Pb2+ adsorption showed almost no change, while after the adsorption of HA, new peaks were observed at 1692 and 1736 cm−1 in PSMPs due to the adsorption of HA on PSMPs, which originated from the C=O bond of carboxyl group in HA. After PSMPs adsorbed HA and Pb2+, the increased intensity of the peaks at 1692 and 1736 cm−1 and the new peak at 3385 cm−1 (caused by the O–H stretching vibrations) indicated that more HA was adsorbed onto PSMPs. Moreover, the spectrum of the PSMPs-HA-Pb2+ system had a shift of about 8 cm−1 in the C=O intensity (1692 and 1736 cm−1) compared with that of PSMPs-HA system, confirming the complexation of HA with Pb2+, and indirectly proving the increase adsorption of Pb2+ onto PSMPs by HA49.
Figure 4 showed the XPS spectra of the PSMPs before and after adsorption. From survey spectra (Fig. 4a), the virgin PSMPs particles were consisted of carbon and trace amounts of oxygen. The oxygen atoms contained in the PSMPs may be caused by oxidation during processing or transportation50. The C1s spectra of PSMPs (Fig. 4b) showed little difference before and after Pb2+ adsorption, while the intensities of C–O (peak at 285.58 eV) and C=O (peak at 288.08 eV) increased after HA adsorption, indicating that HA introduced more oxygen-containing functional groups on PSMPs surface. The high resolution Pb 4f spectra (Fig. 4c) showed two distinguishable peaks that located at 138.08 eV (Pb 4f7/2) and 142.88 eV (Pb 4f5/2) with an energy separation of 4.8 eV, which were ascribed to Pb2+ species adsorbed with the participation of particles oxygen-containing functional groups45. In addition, the intensity of Pb 4f. peak increased significantly in the presence of HA, indicating that HA promoted the adsorption of Pb2+ on PSMPs, which was consistent with the results of SEM–EDS and FT-IR.
Fluorescence quenching analysis of HA in adsorption process
The three-dimensional fluorescence excitation-emission matrix (3DEEM) spectra of HA (Supplementary Fig. S8) showed that the texted HA molecules contained two major fluorescence peaks, i.e., peak A (Ex/Em: 275/481 nm) and peak B (Ex/Em: 455/516 nm). Peak A with high intensity was the fluorescence peak of terrestrial humic-like, while peak B with a lower intensity might be related to microbial metabolism51. The peak A with higher intensity was selected for fluorescence quenching analysis in this study.
In HA-Pb2+ system and PSMPs-HA-Pb2+ system, the fluorescence quenching curves of HA under different conditions were shown in Supplementary Figs. S9–S16. The decrease in fluorescence intensity with increasing Pb2+ concentrations revealed a chemical reaction between HA and Pb2+. It was also observed that the maximum emission wavelength of HA shifted toward the lower wavelength (i.e. blue shift) with increasing Pb2+ concentration, suggesting a possible reduction of conjugated bonds in the chain structure, or the occurrence of π−π* transition in the reaction process49.
The linear Stern–Volmer equation was applied to reveal the binding behavior of HA with Pb2+, as shown in Figs. 5 and 6, and the model parameter KSV was shown in Table 1. In the PSMPs-HA-Pb2+ system, the fluorescence quenching of HA increased with the increase of pH and the decrease of the ionic strength (Na+ and Ca2+), which was consistent with the trend in the HA-Pb2+ system, demonstrating that PSMPs did not change the binding mode of HA and Pb2+. The fluorescence intensity of HA was greatly affected by pH when the ionic strength of the solution was constant. This was because the exposed fluorophore of HA decreased due to the constricted structure of HA molecule at low pH condition, which resulting in the reduction of complexation between HA and Pb2+47. Under the same pH condition, the effect of ionic strength on the initial fluorescence intensity of HA was mainly caused by the reaction between background ions and fluorophore, which weakened the fluorescence intensity of HA. Therefore, the indirect adsorption of Pb2+ on PSMPs through HA decreased at low pH and high ionic strength condition. Compared to the HA-Pb2+ system, the parameter KSV value were higher for the PSMPs-HA-Pb2+ system at the same HA concentration (5.00 mg·C/L), indicating that more HA was adsorbed on the surface of PSMPs and bounded to Pb2+, and the indirect adsorption of Pb2+ (in the form of HA-Pb2+ compounds) on PSMPs increased22. In PSMPs-HA-Pb2+ system, the KSV value decreased with the decrease of HA concentration, which was attributed to the weak initial fluorescence intensity of HA at lower concentrations and the small change in fluorescence quenching when combined with different concentrations of Pb2+.
Site energy distribution analysis for adsorption of Pb2+ onto PSMPs promoted by HA
The site energy distribution theory (SEDT) provides relevant information about the energies of adsorption sites, such as high-, low- and average energy sites, and the energy distribution heterogeneity, which can further explain the adsorption mechanism52. To further exploring the mechanism of Pb2+ adsorbed on PSMPs, the site energy distribution on the surface of PSMPs was calculated based on the Langmuir model and the results were shown in Supplementary Figs. S17 and S18. It could be seen that the E* values gradually decreased with the increase of Qe, indicating that the surface energy distribution of PSMPs was heterogeneous, and the amount of high energy sites were limited. In the adsorption process of PSMPs-HA-Pb2+ systems, Pb2+ or HA-Pb2+ were preferentially adsorbed to the high-energy adsorption sites on PSMPs, followed by low-energy adsorption sites53. This was consistent with the adsorption of Cr(VI) on engineered silicate nanoparticles54.
Figures 7 and 8 showed that the F(E*) curves of Pb2+ adsorption on PSMPs were all unimodal and quasi-Gaussian55. The area under the F(E*) curve versus adsorption site energy revealed the amount of the available adsorption sites, which could be interpreted as the maximum adsorption capability56. The μ(E*) was higher in the presence of HA than in the absence of HA and increased with increasing HA concentration (Tables 2 and 3), illustrated that the presence of HA could introduce some new adsorption sites, thus enhanced the adsorption site energy on the PSMPs surface and promoted the adsorption of Pb2+. In addition, the standard deviation σe* which was used to characterize the energy heterogeneity of Pb2+ adsorption on PSMPs increased slightly as the increase of HA concentration. This indicated that the adsorption heterogeneity of PSMPs increased after partial HA adsorption on the PSMPs surface, which was consistent with the SEM results.
The solution pH and ionic strength also affect the site energy distribution of PSMPs. The values of E* and μ(E*) were higher at pH 6.0 than those at pH 3.0, indicating that there were more adsorption sites for PSMPs at pH 6.0 and resulting in higher adsorption affinity. With increasing ionic strength the site energy decreased, because more binding sites were occupied by salt ions and thus reduced the adsorption capacity of PSMPs. The value of σe* for different pH and ionic strength condition were little difference, illustrating that changing the solution pH and ionic strength did not essentially change the surface structure of PSMPs.
Conclusion
In this article, the adsorption of Pb2+ onto PSMPs under different HA concentration was investigated by batch experiments, and the effect of pH and ionic strength condition was also discussed. The adsorption kinetic and isotherm model of Pb2+ onto PSMPs conform to the pseudo-second-order kinetics model and Langmuir model, indicating that the process was single layer adsorption and chemical adsorption. Regardless of the presence of HA, the increase of pH and the decrease of ionic strength were favorable for the adsorption of Pb2+ on PSMPs surface. HA promoted the adsorption of Pb2+ onto PSMPs, and the higher the concentration of HA the greater the adsorption. SEM–EDS, FT-IR and XPS analysis before and after PSMPs HA/Pb2+ adsorption suggested that HA adsorbed on PSMPs introduced more functional groups (-COOH and -OH) on the surface of PSMPs and promoted the indirect adsorption capacity of Pb2+. The fluorescence quenching of HA in PSMPs-HA-Pb2+ systems was stronger than that in HA-Pb2+ systems, indicating that more HA was adsorbed on the surface of PSMPs, and the indirect adsorption of Pb2+ increased. SEDT analysis showed that the surface energy distribution of PSMPs was heterogeneous, and the addition of HA enhanced the μ(E*) and σe* value of PSMPs, which was favorable for the adsorption of Pb2+. The heterogeneity of PSMPs at different pH and ionic strength were similar, indicating that the change of solution conditions did not affect the structure of PSMPs.
These findings were helpful to understand the adsorption process and mechanism of HA affecting on Pb2+ adsorption by PSMPs, and could provide a basis for investigating the adsorption of other heavy metals (e.g., Cu2+, Zn2+, Cr3+) onto different MPs (e.g., PE, PVC, PA) in aqueous environment. What’s more, this research was contribute to further evaluating the environmental risks of MPs.
Data availability
All data generated or analysed during this study are included in this published article [and its supplementary information files].
References
Courrtney, A., Joel, E. B. & Holly, A. B. Proceedings of the International Research Workshop on the Occurrence, Effects, and Fate of Microplastic Marine Debris, NOAA Technical Memorandum NOS-OR & R-30. NOAA. https://repository.library.noaa.gov/view/noaa/2509 (2008).
Alimi, O. S., Budarz, J. F., Hernandez, L. M. & Tufenkji, N. Microplastics and nanoplastics in aquatic environments: Aggregation, deposition, and enhanced contaminant transport. Environ. Sci. Technol. 52, 1704–1724 (2018).
Hidalgo-Ruz, V., Gutow, L., Thompson, R. C. & Thiel, M. Microplastics in the marine environment: A review of the methods used for identification and quantification. Environ. Sci. Technol. 46, 3060–3075 (2012).
Desforges, J. P. W., Galbraith, M., Dangerfield, N. & Ross, P. S. Widespread distribution of microplastics in subsurface seawater in the NE Pacific Ocean. Mar. Pollut. Bull. 79, 94–99 (2014).
Fischer, E. K., Paglialonga, L., Czech, E. & Tamminga, M. Microplastic pollution in lakes and lake shoreline sediments—A case study on Lake Bolsena and Lake Chiusi (central Italy). Environ. Pollut. 213, 648–657 (2016).
Tang, S., Lin, L., Wang, X., Feng, A. & Yu, A. Pb(II) uptake onto nylon microplastics: Interaction mechanism and adsorption performance. J. Hazard. Mater. 386, 121960 (2019).
Lu, Y. et al. Uptake and accumulation of polystyrene microplastics in zebrafish (Danio rerio) and toxic effects in liver. Environ. Sci. Technol. 50, 4054–4060 (2016).
Rodriguez-Seijo, A. et al. Histopathological and molecular effects of microplastics in Eisenia andrei Bouché. Environ. Pollut. 220, 495–503 (2016).
Lei, L., Wu, S., Lu, S., Liu, M. & He, D. Microplastic particles cause intestinal damage and other adverse effects in zebrafish Danio rerio and nematode Caenorhabditis elegans. Sci. Total Environ. 619–620, 1–8 (2018).
Brennecke, D., Duarte, B., Paiva, F., Caçador, I. & Canning-Clode, J. Microplastics as vector for heavy metal contamination from the marine environment. Estuar. Coast. Shelf Sci. 178, 189–195 (2016).
Hodson, M. E., Duffus-Hodson, C., Clark, A., Prendergast-Miller, M. T. & Thorpe, K. L. Plastic bag derived-microplastics as a vector for metal exposure in terrestrial invertebrates. Environ. Sci. Technol. 51, 4714–4721 (2017).
Holmes, L. A., Turner, A. & Thompson, R. C. Adsorption of trace metals to plastic resin pellets in the marine environment. Environ. Pollut. 160, 42–48 (2012).
Gao, F. et al. Study on the capability and characteristics of heavy metals enriched on microplastics in marine environment. Mar. Pollut. Bull. 144, 61–67 (2019).
Wang, F. et al. Adsorption characteristics of cadmium onto microplastics from aqueous solutions. Chemosphere 235, 1073–1080 (2019).
Wang, Q. et al. The adsorption behavior of metals in aqueous solution by microplastics effected by UV radiation. J. Environ. Sci. 87, 272–280 (2020).
Jozef, K., Sawomir, D., Magdalena, W. K. & Petr, B. Uptake and phytotoxicity of lead are affected by nitrate nutrition and phenolic metabolism. Environ. Exp. Bot. 178, 104158 (2020).
Guo, H. Antioxidant nutrients and lead toxicity. Toxicology 180, 33–34 (2002).
Bellinger, D. C. & Needleman, H. L. Intellectual impairment and blood lead levels. N. Engl. J. Med. 349, 500–502 (2003).
Lee, J. W. et al. Toxic effects of lead exposure on bioaccumulation, oxidative stress, neurotoxicity, and immune responses in fish: A review. Environ. Toxicol. Pharmacol. 68, 101–108 (2019).
Li, X., Ma, L., Li, Y., Wang, L. & Zhang, L. Endophyte infection enhances accumulation of organic acids and minerals in rice under Pb2+ stress conditions. Ecotoxicol. Environ. Saf. 174, 255–262 (2019).
Zou, J., Liu, X., Zhang, D. & Yuan, X. Adsorption of three bivalent metals by four chemical distinct microplastics. Chemosphere 248, 126064 (2020).
Fu, Q., Tan, X., Ye, S., Ma, L. & Tang, Y. Mechanism analysis of heavy metal lead captured by natural-aged microplastics. Chemosphere 270, 128624 (2020).
Ahechti, M., Benomar, M., El Alami, M. & Mendiguchía, C. Metal adsorption by microplastics in aquatic environments under controlled conditions: Exposure time, pH and salinity. Int. J. Environ. Anal. Chem. 102, 1118–1125 (2020).
Godoy, V., Blazquez, G., Calero, M., Quesada, L. & Martin-Lara, M. A. The potential of microplastics as carriers of metals. Environ. Pollut. 255, 113363 (2019).
Kováik, J., Bujdo, M. & Babula, P. Impact of humic acid on the accumulation of metals by microalgae. Environ. Sci. Pollut. Res. 25, 1–7 (2018).
Prado, A. et al. Studies on copper(II)- and zinc(II)-mixed ligand complexes of humic acid. J. Hazard. Mater. 136, 585–588 (2006).
Xiong, J. et al. Lead binding to soil fulvic and humic acids: NICA-Donnan modeling and XAFS spectroscopy. Environ. Sci. Technol. 47, 11634–11642 (2013).
Abdurahman, A. et al. Adsorption of dissolved organic matter (DOM) on polystyrene microplastics in aquatic environments: Kinetic, isotherm and site energy distribution analysis. Ecotoxicol. Environ. Saf. 198, 110658 (2020).
Li, X., Mei, Q., Chen, L., Zhang, H. & Dong, B. Enhancement in adsorption potential of microplastics in sewage sludge for metal pollutants after the wastewater treatment process. Water Res. 157, 228–237 (2019).
Ma, J. et al. Natural organic matter resistant powder activated charcoal supported titanate nanotubes for adsorption of Pb(II). Chem. Eng. J. 315, 191–200 (2017).
Li, S. et al. Aggregation kinetics of microplastics in aquatic environment: Complex roles of electrolytes, pH, and natural organic matter. Environ. Pollut. 237, 126–132 (2018).
Li, N. & Lee, H. K. Solid-phase extraction of polycyclic aromatic hydrocarbons in surface water: Negative effect of humic acid. J. Chromatogr. A 921, 255–263 (2001).
Zheng, H. et al. Investigation of the adsorption mechanisms of Pb(II) and 1-naphthol by β-cyclodextrin modified graphene oxide nanosheets from aqueous solution. J. Colloid Interface Sci 530, 154–162 (2018).
Ma, H., Allen, H. E. & Yin, Y. Characterization of isolated fractions of dissolved organic matter from natural waters and a wastewater effluent. Water Res. 35, 985–996 (2001).
Duan, G., Gao, Z., Zhong, H., Ma, X. & Wang, S. Highly efficient poly(6-acryloylamino-N-hydroxyhexanamide) resin for adsorption of heavy metal ions. J. Environ. Manag. 308, 114631 (2022).
Liu, W., Sun, W., Han, Y., Ahmad, M. & Ni, J. Adsorption of Cu(II) and Cd(II) on titanate nanomaterials synthesized via hydrothermal method under different NaOH concentrations: Role of sodium content. Colloids Surf. A 452, 138–147 (2014).
Yang, S. et al. Effects of humic acid on copper adsorption onto few-layer reduced graphene oxide and few-layer graphene oxide. Carbon 75, 227–235 (2014).
Bradl, H. B. Adsorption of heavy metal ions on soils and soils constituents. J. Colloid Interface Sci. 277, 1–18 (2004).
Yang, K., Miao, G., Wu, W., Lin, D. & Xing, B. Sorption of Cu2+ on humic acids sequentially extracted from a sediment. Chemosphere 138, 657–663 (2015).
Wta, B. et al. Proton binding to soil humic and fulvic acids: Experiments and NICA-Donnan modeling. Colloids Surf. A 436, 1152–1158 (2013).
Holmes, L. A., Turner, A. & Thompson, R. C. Interactions between trace metals and plastic production pellets under estuarine conditions. Mar. Chem. 167, 25–32 (2014).
Wijesena, R. N., Tissera, N. D., Rathnayaka, V., Silva, R. & Silva, K. Colloidal stability of chitin nanofibers in aqueous systems: Effect of pH, ionic strength, temperature & concentration. Carbohyd. Polym. 235, 116024 (2020).
Zhao, G., Li, J., Ren, X., Chen, C. & Wang, X. Few-layered graphene oxide nanosheets as superior sorbents for heavy metal ion pollution management. Environ. Sci. Technol. 45, 10454–10462 (2011).
Wang, C. et al. Adsorption behavior of lead on aquatic sediments contaminated with cerium dioxide nanoparticles. Environ. Pollut. 219, 416–424 (2016).
Bardestani, R., Roy, C. & Kaliaguine, S. The effect of biochar mild air oxidation on the optimization of lead(II) adsorption from wastewater. J. Environ. Manag. 240, 404–420 (2019).
Wang, X. S. Batch sorption of lead (II) from aqueous solutions using natural kaolinite. Int. J. Environ. Waste Manag. 8, 258–272 (2011).
Gezici, O., Kara, H., Yanık, S., Ayyildiz, H. F. & Kucukkolbasi, S. Investigating sorption characteristics of copper ions onto insolubilized humic acid by using a continuously monitored solid phase extraction technique. Colloids Surf. A 298, 129–138 (2007).
Chen, W., Ouyang, Z. Y., Qian, C. & Yu, H. Q. Induced structural changes of humic acid by exposure of polystyrene microplastics: A spectroscopic insight. Environ. Pollut. 233, 1–7 (2018).
Zhang, Z., Lü, C., Jiang, H., Gao, M. & Yu, Z. Nature differences of fulvic acid fractions induced by extracted sequence as explanatory factors for binding characteristics of Cu2+. Chemosphere 191, 458–466 (2017).
Mao, R. et al. Aging mechanism of microplastics with UV irradiation and its effects on the adsorption of heavy metals. J. Hazard. Mater. 393, 122515 (2020).
Coble, P. G. Characterization of marine and terrestrial DOM in seawater using excitation-emission matrix spectroscopy. Mar. Chem. 51, 325–346 (1996).
Carter, M. C., Kilduff, J. E. & Weber, W. J. Site energy distribution analysis of preloaded adsorbents. Environ. Sci. Technol. 29, 1773–1780 (1995).
Shi, H., Sun, Y., Zhao, X. & Qu, B. Influence on sorption property of Pb by fractal and site energy distribution about sediment of Yellow River. Procedia Environ. Sci. 18, 464–471 (2013).
Liao, P. et al. Immobilization of Cr(VI) on engineered silicate nanoparticles: Microscopic mechanisms and site energy distribution. J. Hazard. Mater. 383, 121145 (2020).
Huang, L. et al. High-resolution insight into the competitive adsorption of heavy metals on natural sediment by site energy distribution. Chemosphere 197, 411 (2018).
Yan, B. & Niu, C. H. Modeling and site energy distribution analysis of levofloxacin sorption by biosorbents. Chem. Eng. J. 307, 631–642 (2017).
Acknowledgements
This work was supported by the Natural Science Foundation of China (No. 41877462).
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X.L. and F.Z. conceived and designed the experiments. X.L. and W.L. performed adsorption experiments and data analysis. S.W., and R.G. prepared and characterized samples. A.A. and H.W. contributed in instrumental analysis and testing. All the authors reviewed the manuscript and discussed the experimental implementation and the results. X.L. and W.L. contributed in writing the manuscript.
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Lu, X., Zeng, F., Wei, S. et al. Effects of humic acid on Pb2+ adsorption onto polystyrene microplastics from spectroscopic analysis and site energy distribution analysis. Sci Rep 12, 8932 (2022). https://doi.org/10.1038/s41598-022-12776-3
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DOI: https://doi.org/10.1038/s41598-022-12776-3
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