Immobilization of Potentially Toxic Elements (PTE) by Mineral-Based Amendments: Remediation of Contaminated Soils in Post-Industrial Sites

Abstract

In many post-industrial sites, the high contents and high mobility of different potentially toxic elements (PTEs) make the soils unsuitable for effective management and use. Therefore, immobilization of PTE seems to be the best remediation option for such areas. In the present study, soil samples were collected in post-industrial areas in Northeastern Poland. The analyzed soil was characterized by especially high contents of Cd (22 mg·kg⁻¹), Pb (13 540 mg·kg⁻¹), and Zn (8433 mg·kg⁻¹). Yellow lupine (Lupinus luteus L.) and two types of mineral-based amendments were used to determine their combined remediation effect on PTE immobilization. A greenhouse pot experiment was conducted to evaluate the influence of chalcedonite and halloysite on plant growth, chlorophyll a fluorescence, the leaf greenness index (SPAD), PTE uptake, and the physicochemical properties and toxicity of soil. The application of chalcedonite resulted in the greatest increase in soil pH, whereas halloysite contributed to the greatest reduction in the contents of Ni, Pb, Zn, and Cr in soil, compared with the control treatment. The addition of halloysite significantly increased plant biomass. The application of mineral-based amendments increased the ratio of variable fluorescence to maximum chlorophyll fluorescence (Fv/Fm) in yellow lupine leaves. The leaf greenness index was highest in plants growing in soil amended with chalcedonite. The results of this study suggest that mineral-based amendments combined with yellow lupine could potentially be used for aided phytostabilization of multi-PTE contaminated soil in a post-industrial area.

1. Introduction

Rapid industrialization and population growth in the last century have led to adverse changes in the natural environment [1]. Soil, water, and air pollution can pose considerable threats for human health and distort the natural balance of ecosystem components [2]. Anthropogenic pressure disrupts biogeochemical cycles and increases the contents of PTE in the environment, which creates serious problems on the local and global scale [3]. Efforts are being made to restore degraded soils and decrease the content of contaminating substances below the established threshold values [4]. In many cases, soil quality standards cannot be met for technical or financial reasons; therefore, the main aim of restoration is to reduce contamination availability and its adverse environmental impact.

Phytoremediation poses a viable alternative to other restoration methods [5]. It can be used independently or in combination with conventional methods of soil and water remediation. Phytoremediation is effective in purifying not only small but also large degraded areas [6]. Phytostabilization has attracted considerable interest in recent years because it is a technique which relies on plants to immobilize pollutants in soil and reduce their bioavailability in the environment [7]. Contaminants like PTE are immobilized when they are absorbed and accumulated in plant roots, adsorbed on root surfaces, and precipitated in the rhizosphere [8]. The chemical compounds secreted by plant roots into the rhizosphere decrease the bioavailability of PTE. This remediation method protects soil from further degradation, including erosion, and the immobilized compounds are less likely to migrate to other links in the food chain [9]. Phytostabilization effectively diminishes ecological risk in soil containing both organic and inorganic pollutants. Another advantage is the fact that in areas where the phytostabilization is applied, the above-ground plant parts have a low content of PTE; therefore, they can be effectively used to generate energy in all biomass conversion processes (combustion, co-combustion, fermentation).

Compounds that deactivate and immobilize PTE ions in soil can be additionally used in phytostabilization. Mineral-based amendments such as phosphogypsum [10], calcium carbonate, bentonite [11], sulfo-calcic fly ash [12], mixtures of diammonium phosphate and hydroxyapatite [13], calcium carbonate [14], hydrated lime [15], diatomite, and dolomite [16] have been described in the literature. The effectiveness of phytostabilization is determined by the type and quantity of soil amendments. Therefore, effective and inexpensive compounds of natural origin are being researched, including mineral-based amendments such as chalcedonite and halloysite. Chalcedonite is a siliceous rock, and its chemical and phase composition make it highly suitable for a wide range of applications [17]. Chalcedonite has a homogenous chemical composition with an estimated 94% content of silicon dioxide (SiO₂). Chalcedonite rock is composed mainly of chalcedony with small amounts of quartz, opal, iron hydroxides, pyrite, manganese compounds, and clay minerals. Chalcedonite is a mesoporous material with a relatively uniform pore structure and a total pore volume of 0.03–0.04 cm³·g⁻¹ [18]. Halloysite is composed of nanotubes, and it is characterized by high porosity and specific surface area, high cation exchange capacity, and ease of chemical and mechanical processing. Although it contains trace amounts of contaminants, it is highly stable across a wide pH range [19]. The chemical composition of halloysite is highly similar to kaolin. The main structural component in this group of minerals is the 1:1 kaolinite group of clay minerals with the crystal-chemical formula Al₄Si₄O₁₀(OH)₈ [20]. Halloysite has many applications in engineering and environmental protection, and it is widely used as a mineral adsorbent for removing toxic substances and PTE from water and wastewater [21,22]. Halloysite has not commonly been tested because, although a large amount of it is available, there are only three halloysite mines in the world. Halloysite is characterized by a large specific surface area (approximately 65,000–400,000 m²·kg⁻¹) and considerable porosity (60–70%) [23]. Despite the favorable properties of chalcedonite and halloysite, there has been little research into their application in assisted phytostabilization of chemically degraded soils.

In view of the above, the aim of this study was to evaluate the effect of mineral-based amendments on assisted phytostabilization of soil heavily contaminated with mixed PTE. The phytotoxic and phytochemical properties of the soil and the chemical composition of the plants were analyzed, and chlorophyll a fluorescence and the leaf greenness index (SPAD) were determined.

2. Materials and Methods

2.1. Mineral-Based Amendments and Experimental Design

Two mineral-based amendments, i.e., chalcedonite (limited liability company Chalcedon Poland, Inowłódz, Poland) and halloysite (“Dunino” strip mine, Intermark Company, Legnica, Poland), were mixed with soil in the amount of 3.0% (w/w). Soil without the amendments (0.0%, w/w) was the control treatment. Soil samples were thoroughly mixed, and pots filled with soil with a moisture content at 60% of water holding capacity were left in a dark room for over 3 weeks to equilibrate the soil mixture. Each treatment was replicated three times. Scanning electron microscope (SEM) images of mineral-based amendments are presented in Figure 1. The oxides content in soil amendments was measured using X-ray diffraction (XRD) analysis (Philips X-ray Diffractometer with X’Celerator Detector), while the specific surface area was measured with a Micromeritics ASAP 2020 BET N2 (Norcross, GA, USA).

Table 1. Properties of mineral-based amendments.

Parameter	Chemical Composition in Oxide (wt. %)	Specific Surface Area (m2·g−1)	pH
Chalcedonite	SiO2—89.06 ± 0.46; Al2O5—9.33 ± 0.14; K2O—1.21 ± 0.08; MgO—0.40 ± 0.011	7.44	7.12
Halloysite	SiO2—39.6, Al2O3—37.0, Fe2O3—16.1, TiO2—2.30, CaO—0.66, MgO—0.13, Na2O—0.04, K2—0.05; P2O5—0.52	75.0	7.66

presents selected properties of the mineral-based amendments used in the experiment.

The experiment was conducted in a naturally ventilated greenhouse. The tested plant species was yellow lupine (L. luteus) cv. Perkoz which was planted in 5.0 kg polyethylene pots. The plants were watered every other day with deionized water to maintain 60% of the maximum water holding capacity of the soil. At the end of the experiment (approximately 54 days after sowing), lupine plants were harvested, weighed, and separated into the roots and above-ground parts.

2.2. Soil from Post-Industrial Areas Used in the Experiment

In this study, samples of soil heavily co-contaminated with Cd, Pb, and Zn were collected from a depth of 0–20 cm in post-industrial areas in Northeastern Poland (53°47′3.48″ N; 20°30′52.56″ E) using the method described by Pan et al. [24]. The study area mainly stores ferrous and non-ferrous metal waste since 1946. About 150 kg of soil were sampled from several dozen points located within an area of 1000 m². At each sampling point, 5 soil samples were collected using a soil auger and mixed to achieve a composite soil sample representing a given sampling point. Before the pot experiment, the samples were air-dried and passed through a 2 mm nylon sieve. The soil, classified as loamy fine sand, was composed of 76% sand, 23% silt, and 1% clay fractions. The selected physicochemical properties of the soil are presented in Table 1.

2.3. Soil Analysis

Before the experiment, soil samples were assayed for pH and electrical capacity (EC) in distilled water extracts (1:2.5 w/v) using a pH-meter (HI 221) and cation exchange capacity (CEC), calculated as the sum of hydrolytic acidity (in 1M Ca(CH₃COO)₂) and exchangeable bases (in 0.1 M HCl). Soil organic matter was determined by combustion at 550 °C. The total content of PTE (Cd, Cr, Cu, Ni, Pb, Zn) was determined with a flame atomic absorption spectrometer (FAAS) (Varian AA28OFS, Mulgrave, Australia) using the U.S. Environmental Protection Agency Method 3050B after soil digestion in a mixture of concentrated HCl, HNO₃, and H₂O₂ in a microwave oven (MARSXpress, CEM Corporation, Matthews, NC, USA) using a single-stage program (ramp to temperature for 30 min, hold samples at 170 °C for 45 min). The extracts after mineralization were filtered through Whatman filters into 50 mL glass flasks. The accuracy of PTE analysis by FAAS was validated by analyzing the reference material, CRM 142 R.

2.4. Plant Material Analysis

At the end of the experiment, the harvested L. luteus plants were divided into shoot and root parts. The plant material was carefully washed with ultrapure water to remove soil particles, and then air-dried at room temperature. Before chemical analyses, the plants were powdered using an analytical mill (Retsch type ZM300, Hann, Germany) and kept at ambient temperature. The contents of PTE in the above-ground parts and roots of plants were determined by mineralizing them in a microwave oven with concentrated HNO₃.

Chlorophyll a fluorescence in the plants was measured during the growing season with the Handy-PEA portable chlorophyll fluorimeter (Hansatech Instruments Ltd., Pentney, UK). Measurements were conducted on two randomly selected, fully developed leaves, and the results were averaged (five plants per pot, two measurements per plant). The maximum quantum efficiency of PSII (Fv/Fm ratio; Fv is the variable fluorescence; Fm is the maximum fluorescence), as an indicator of plant adaptation to dark, was determined on lupine leaves three times during the experiment. Before the measurements, leaves were covered with clips for 30 min for dark adaptation. Fluorescence emission was induced on 4 mm² of leaf surface area with a light intensity of 3000 μmol m⁻² s⁻¹. Maximum fluorescence (MF) was measured for 100 ms. Fluorescence kinetics were analyzed in the Pocket PEA Plus V1.10 program (Hansatech Instruments Ltd., Pentney, UK). The leaf greenness index (SPAD) was determined on ten leaves in each plant with the SPAD 502 chlorophyll meter (Konica Minolta, Tokyo, Japan). The leaf greenness index was expressed in dimensionless SPAD units. All measurements were conducted in triplicate.

2.5. Ecotoxicological Analysis

The phytotoxicity of contaminated soils was determined with the Phytotoxkit seed germination biotest and an early growth microbiotest (Microbiotests Inc., Ghent, Belgium). Phytotoxicity analyses were also carried out in soils with mineral-based amendments (halloysite and chalcedonite). The analyses were conducted in triplicate, and Phytotoxkit soil was the control treatment. Phytotoxicity tests were performed with the use of sorghum (Sorghum saccharatum L.) seeds. Observations were conducted for seven days, and digital images were acquired every day. Root length was measured by digital image analysis in the Image Tool 3.0 program (UTHSCSA, San Antonio, TX, USA). The results were used to calculate the percentage inhibition of seed germination and root growth with the use of the following formula:

I = ((A − B))/A × 100,

(1)

where: I—inhibition (%), A—seed germination or the length of roots in control soil, B—seed germination or the length of roots in the tested soils (with and without mineral-based amendments).

2.6. Statistical Analysis

The results of the experiment were processed statistically in the Statistica 13.3 program (San Diego, CA, USA). The normality of data distribution in every independent group was determined in the Shapiro–Wilk test, and the residuals were additionally checked for normality. The homogeneity of variance was verified by Levene’s test. The significance of differences between means was determined by one-way ANOVA (F-test). Significant differences (p < 0.05) between the mean values of different treatments were evaluated and compared in Tukey’s range test. The results were also subjected to Principal Component Analysis (PCA) in the XLStat program (Addinsoft, Paris, France).

3. Results

3.1. Soil Parameters

The analyzed soils had a pH of 7.54 ± 0.4, pointing to alkaline conditions. The mean contents of PTE are presented in

Table 2. Selected properties of the analyzed soil.

Parameter	Unit	Value	Acceptable Values a
pH	-	7.54 ± 0.4	-
Electrical conductivity	mS·cm−1	0.84 ± 0.3	-
Organic matter	%·d.m.	11 ± 2.1	-
Cation Exchange Capacity	C mol (+)·kg−1	51.9 ± 2.7	-
Cadmium (Cd)	mg·kg−1	22 ± 2.5	15
Copper (Cu)	mg·kg−1	496 ± 144.4	600
Chromium (Cr)	mg·kg−1	352 ± 61.1	500
Nickel (Ni)	mg·kg−1	113 ± 24.5	300
Lead (Pb)	mg·kg−1	13,540.0 ± 669.6	600
Zinc (Zn)	mg·kg−1	8430 ± 1376.5	1000

^a threshold values set forth by the Regulations of the Polish Ministry of the Environment [25]. The values in bold significantly exceed threshold contents.

. Soil contamination was evaluated based on the classification set forth in the Regulation of the Polish Ministry of the Environment [25]. The contents of Cd, Pb, and Zn in degraded soils from post-industrial areas exceeded the thresholds values given in the above classification. The contents of the remaining PTE were within the safe range.

3.2. Soil Parameters after the Addition of Mineral-Based Amendments

The pH of soil from post-industrial areas was affected by the type of mineral-based amendments (Figure 2). Chalcedonite induced the greatest increase in soil pH, from 8.14 in the control treatment to 8.25. The PTE content of phytostabilized soil is presented in Figure 3. The total contents of Ni, Pb, Zn, and Cr were most effectively reduced by halloysite, relative to non-amended control soil. Chalcedonite decreased the total amounts of Cu and Cd in the analyzed soil.

3.3. Plant Growth after the Addition of Mineral-Based Amendments

The yield of the above-ground biomass of L. luteus is presented in Figure 4. The analyses of plant growth and development indicate that chalcedonite and halloysite increased the yield of the above-ground biomass of L. luteus. Halloysite contributed to the greatest increase in the yield of above-ground biomass relative to the control treatment.

3.4. PTE Accumulation in L. luteus

The effect of mineral-based amendments on PTE accumulation in the roots and above-ground biomass of L. luteus is presented in Figure 5. The analyzed PTE were accumulated mostly in lupine roots. In comparison with the non-amended control treatment, halloysite led to the greatest accumulation of Ni and Cr, whereas chalcedonite resulted in the greatest accumulation of Cd in lupine roots.

3.5. Chlorophyll Fluorescence

Chalcedonite and halloysite increased the value of Fv/Fm in lupine leaves relative to the control treatment (Figure 6). The Fv/Fm ratio was determined at 0.73–0.74 in control soil, 0.78–0.8 in soil with the addition of halloysite, and 0.77–0.81 in soil amended with chalcedonite.

3.6. Leaf Greenness Index (SPAD)

The leaf greenness index of lupine plants differed significantly across treatments containing the tested mineral-based amendments (Figure 7). In the first month of the experiment, the leaf greenness index was highest in soil containing chalcedonite (37.555 SPAD). The analyzed parameter was 22.0% lower on average (30.82 SPAD) in non-amended control soil. Similar trends were observed during the second and the third measurement.

3.7. Phytotoxicity

In phytotoxicity analyses of contaminated soil, the percentual inhibition of seed germination (GI) was generally lower (16.6% on average for all samples) than the percentage inhibition of root growth (RI) (41.9% on average for all samples) (Figure 8). The tested mineral-based amendments had no significant effect on the germination of S. saccharatum seeds. Chalcedonite added to contaminated soil significantly differentiated the length of S. saccharatum roots relative to non-amended contaminated soil. The differences in root length observed in the tested plants growing in soil amended with halloysite were not statistically significant.

3.8. Statistical Analysis

The suitability of the data for factor analysis was assessed using Kaiser-Meyer-Olkin (KMO) and Barlett Tests. The value of KMO = 0.518 confirmed the suitability of the data for factor analysis. Two factors with eigenvalues greater than 1 were identified, where the ratio of the variance explained by each factor to the total variance decreased gradually (

Table 3. Varimax rotated factor matrix for the analyzed dataset.

Variables	VF1	VF2
Biomass	−0.941 ***	0.339
pH	−0.010	−1.000 *
Cu a	0.604	0.797 ***
Cu b	0.935 ***	0.355
Cu c	0.808 ***	0.589
Ni a	0.970 ***	0.241
Ni b	0.995 ***	0.097
Ni c	−0.983 ***	0.182
Cd a	0.382	0.924 ***
Cd b	0.711 **	0.703
Cd c	−0.980 ***	0.198
Pb a	0.934***	0.356
Pb b	0.410	−0.912 ***
Pb c	−0.243	0.970 ***
Zn a	0.918 ***	0.396
Zn b	0.995 ***	−0.103
Zn c	0.411	0.912 ***
Cr a	0.723 **	0.690
Cr b	−0.263	0.965 ***
Cr c	−0.874 ***	0.486
Eigenvalue	12.634	7.366
Variability (%)	58.734	41.266
Cumulative %	58.734	100.000

* Significant factor loading is bold faced (*** strong > 0.75; ** medium 0.50–0.75; * weak 0.50–0.30) [26] ^a total content in soil; ^b metal contents in the above-ground plant material; ^c metal contents in the root.

and Figure 9). These two factors explained 100% of total variance. The first factor explained 58.73% of total variance. Biomass and the content of Cd, Ni, and Cr in the roots had strong negative loads; the content of Cu, Ni, and Zn in the above-ground parts of the tested plants, the content of Cu and Ni in the roots, and the content of Ni and Zn in the soil had strong positive loads, whereas the Cd content of the above-ground biomass and the Cr content of soil had moderately positive loads. The second factor explained 41.26% of total variance. pH and the Pb content of the above-ground parts had strong negative loads; the content of Cu and Cd in the soil, the content of Pb and Zn in the roots, and the Cr content of the above-ground parts had strong positive loads, whereas biomass had a moderately negative load.

The correlation matrix of PCA data is shown in Table 2. Significant negative correlations were found between biomass vs. the content of Cu in the above-ground parts of plants, Cu in the roots, Ni and Pb in the soil, Pb in the above-ground parts, Zn in the soil, and Zn in the above-ground parts (r = −0.560 to −0.971), whereas significant positive correlations were noted between biomass vs. the content of Ni, Cd, Pb, and Cr in the roots and Cr in the above-ground parts of L. luteus (r = −0.575 to −0.989). Significant negative correlations were also observed between pH vs. the content of Cu and Cd in the soil, Cu in the roots, Cd in the above-ground parts, Pb and Zn in the roots, Cr in the soil, and Cr in the above-ground parts (r = −0.597 to −0.968). The correlation analysis revealed that PTE parameters were strongly correlated with one another.

4. Discussion

In the present study, the total contents of Cd, Pb, and Zn considerably exceeded the threshold levels set forth by the Regulation of the Polish Ministry of the Environment [25]. The effectiveness of phytoremediation in degraded areas can be improved through the addition of amendments that decrease erosion and/or the transfer of PTE to deep soil horizons and reduce the quantity of phytoavailable metals in soil [27]. The applied amendments immobilize PTE in soil, thus contributing to the reinstatement of the physiochemical and functional properties of degraded soils. In the current study, halloysite enhanced the immobilization of metals (Ni, Pb, Zn, and Cr) in soil, which could be attributed to its large specific surface area and cation exchange capacity [22]. Halloysite’s ability to immobilize PTE in contaminated soil was also reported in our previous studies which demonstrated that this mineral-based amendment effectively immobilized Ni [28], Pb, Zn [29], and Cu [30]. PTE-binding affinity is influenced by the granulometric composition, organic matter content, and pH of soil [31]. The mobility of PTEs decreases with an increase in soil pH. Potential toxic elements are less bioavailable in alkaline soils. According to Blake and Goulding [32], the bioavailability of Cd increases at pH > 5.5, the bioavailability of Zn, Ni, and Cu increases at pH 5.0, and the bioavailability of Pb at pH < 4.5. In the present study, the greatest increase in soil pH was observed in the treatment containing chalcedonite. A significant increase in soil pH was also reported by Jin et al. [33] and Abad-Valle et al. [34] who analyzed the effectiveness of mineral-based amendments (nano-hydroxyapatite, sepioloite) in the remediation of PTE-polluted soils, which is consistent with the present findings. Mineral-based amendments can promote assisted phytostabilization by inducing the immobilization of pollutants in soil [29].

In the present study, halloysite and chalcedonite considerably decreased the total PTE content of soil by increasing soil pH and, consequently, reducing the mobility and bioavailability of PTE. High contents of PTE have toxic effects on plants, and they compromise or inhibit plant growth and development [35]. Heavily contaminated soils can be sown with plant species that are highly tolerant of pollution [36]. In the current study, soils contaminated with high levels of PTE were effectively remediated through the combined application of L. luteus and mineral-based amendments. In other studies, mineral-based amendments such as zeolite, CaO, bentonite, and dolomite effectively immobilized PTE in soil and increased the yields of the tested plants [37]. The mechanism by which plant roots absorb PTE is highly complex and involves several processes, including cation exchange across cell walls, intracellular transport and rhizosphere processes [38,39]. Plant cover can limit the migration of PTE to deeper soil horizons and above-ground plant parts by stabilizing pollutants in the rhizosphere [40]. The results of this study validate the above observation. According to the literature, PTE absorbed from the soil solution are more likely to be accumulated in roots than in shoots, proportionally to their content in the soil [41,42]. The analyzed PTE were accumulated mainly in lupine roots, in particular in soil amended with halloysite. In the extensive root system, the mineralization of old roots also increases the organic matter content of soil and promotes the immobilization of contaminating PTE [43]. Other studies have demonstrated that plants used for phytostabilization effectively absorb PTE, and the absorption of Zn, Pb, Cd, and Ni by plant roots generally increases with a rise in pollution levels [29,30]. The applied plants should be characterized by low fertilizer, water, and pesticide requirements, high efficiency of the photosynthetic apparatus, and they should be well adapted to the local climate [44]. Previous research [45,46] and the present findings indicate that PTE impair chlorophyll synthesis and decrease the chlorophyll content of plants. Plant resistance to toxic levels of PTE varies across species and varieties. Despite the fact that PTE are bound by various organic substances (proteins and amino acids), these pollutants decrease the chlorophyll content of plants, thus reducing photosynthetic efficiency [47]. The roots are the first plant organs to come into contact with and respond to PTE in soil, which was also observed in S. saccharatum in this study. The percentual inhibition of seed germination and root growth indicates that the analyzed soil was characterized by low toxicity for the tested plant species.

5. Conclusions

Degraded post-industrial areas are characterized by adverse physicochemical properties, including high contents of PTE, which inhibit the development of vegetation. In the present study, the addition of halloysite to contaminated soil significantly increased L. luteus biomass. The above mineral-based amendment was also most effective in reducing the total contents of Ni, Pb, Zn, and Cr in soil. Chalcedonite led to the highest increase in soil pH relative to the control treatment. The uptake of PTE by L. luteus plants depended on the type of metal and the applied mineral-based amendments. The total content of PTE was higher in the roots than in the above-ground parts of L. luteus plants. The Ni and Cr content in roots was significantly higher in soil amended with halloysite than in the control treatment. The application of mineral-based amendments increased the Fv/Fm ratio in yellow lupine leaves. The leaf greenness index was highest in plants growing in soil amended with chalcedonite. Chalcedonite significantly differentiated the length of S. saccharatum roots.