Formation of the ZnCr₂O₄ Spinel from ZnO and Cr₂O₃

Phase Transformation of Zn- and Cr-Containing Compositions

Based on the hypothesis for AB ₂O₄ spinel formation, the molar ratio of Zn as divalent ion to Cr as trivalent ion was set at 1:2, which is stoichiometrically consistent with the ratio of the two metals in the product phase. From the XRD patterns of the sintered ZC sample series after thermal treatment at 700–1200°C (Fig. 1), the initial crystal phases were identified as ZnO (PDF #89-7102) and Cr₂O₃ (PDF #04-0765). The formation of the ZnCr₂O₄ spinel (PDF #87-0028) was first detected in the sample sintered at 700°C. In the initial stage of the spinel phase (ZnCr₂O₄) formation, a solid-state reaction occurred between the ZnO and Cr₂O₃ due to a nucleation process, subsequently leading to the formation of spinel ZnCr₂O₄ with a cubic face structure (Dixit et al. Reference Dixit, Palani and Singh2015). The potential reaction between ZnO and Cr₂O₃ is expressed as:

(1) $\mathrm{ZnO}\left(\text{orthorhombic}\right)+{\mathrm{Cr}}_2{O}_3\left(\text{orthorhombic}\right)\to {\text{ZnCr}}_2{O}_4\left(\text{octahedron}\right)$

Fig. 1 XRD patterns of sintered ZnO + Cr₂O₃, at 700 to 1200°C for 3 h. The standard patterns retrieved from the ICDD database included ZnO (PDF #89-7102), Cr₂O₃ (PDF #04-0765), and ZnCr₂O₄ (PDF #87-0028)

With increase of sintering temperature, a substantial increase in the intensity of the ZnCr₂O₄ peaks was observed, together with a simultaneous decrease in the peaks of ZnO and Cr₂O₃. At 1000°C, no peaks of ZnO and Cr₂O₃ could be identified after 3 h of sintering, implying complete transformation of both reactants. Subsequently, the diffraction peaks of the ZnCr₂O₄ were sharper and narrower as the sintering temperature increased, which indicated enhancement of the crystalline phase due to the enlargement of the particles (Gene et al. Reference Gene, Saion, Shaari, Kamarudeen and Al-Hada2015).

As Zn and Cr are mixed stoichiometrically in the reaction system, the transformation efficiency for either of the two metals is reflected by their incorporation into the spinel structure. Therefore, a “transformation ratio (TR, %)” index was defined as below, based on the quantification results of all Zn-containing components in the reaction system:

(2) $\mathrm{TR}=\left(\frac{\mathrm{wt}.\%\text{of}{\text{ZnCr}}_2{O}_4}{\mathrm{MW}\text{of}{\text{ZnCr}}_2{O}_4}\right)/\left(\frac{\mathrm{wt}.\%\text{of}{\text{ZnCr}}_2{O}_4}{\mathrm{MW}\text{of}{\text{ZnCr}}_2{O}_4}+\frac{\mathrm{wt}.\%\text{of}\mathrm{ZnO}}{\mathrm{MW}\text{of}\mathrm{ZnO}}\right)$

where MW refers to the molecular weight. A TR value of 100% implies complete transformation of Zn and Cr into the ZnCr₂O₄ spinel structure.

From the TRs summarized in Fig. 2, 70.55% of Zn was transformed into the ZnCr₂O₄ structure even at the lowest temperature in the thermal treatment used in this study. With further increase in the sintering temperature, the TR value of Zn increased continuously until reaching nearly full incorporation (TR = 100%) at 1300°C. The driving forces for mass transfer during thermal treatment are the differences in chemical potential (free enthalpy or molar Gibbs free energy) among the firing materials (Sarıkaya et al. Reference Sarıkaya, Ada and Önal2008). The value of Δ_r G (standard Gibbs free energy) for the reaction between ZnO and Cr₂O₃ at 1000 K is –88.06 kJ mol^–1, leading to the efficient transformation of Zn and Cr into the ZnCr₂O₄ spinel at a relatively lower temperature (Stephen et al. Reference Stephen, Lawrence, Roy and Wallace2007).

Fig. 2 The transformation ratio (TR, %) of Zn into the ZnCr₂O₄ spinel structure after sintering the mixture of ZnO + Cr₂O₃

Incorporation Mechanisms of Zn and Cr into ZnCr₂O₄ Spinel

The XPS spectra of the products obtained through sintering the mixture of ZnO + Cr₂O₃ at 1000°C for 3 h are shown in Fig. 3. A full-scan XPS spectrum (Fig. 3a) was analyzed to study the surface elemental composition of the sample measured. To compensate for the shift in energy due to surface charging, the observed binding energies were all adjusted by assigning the main C 1s peak to 284.8 eV (adventitious carbon). In the XPS survey spectrum of the sample sintered at 1000°C, various peaks were observed corresponding to Zn 2p1/2 (1044.8 eV), Zn 3s (139.8 eV), Zn 3p (89.8 eV), Zn 2p3/2 (1021.8 eV), Cr 3p (61.4 eV), Cr 2p (611.0 eV), and O 1s (530.8 eV). To examine the chemical states of Zn and Cr in the thermal-treated sample, the XPS narrow spectra of Zn, Cr, and O were further analyzed with Gaussian fitting. The peaks at 1021.8 eV and 1044.8 eV were attributed to the binding energies of Zn 2p3/2 and Zn 2p1/2 (Fig. 3b), the perfect symmetrical Zn 2p peaks ruled out the existence of multiple components of Zn in the samples, so Zn was expressed in the lattice in the form of Zn²⁺. However, one cannot specify whether the Zn²⁺ ions were present in ZnO or ZnCr₂O₄, due to the similar XPS peak position of Zn²⁺ ions in these two phases (Song et al. Reference Song, Laudenschleger, Carey, Ruland and Nolan2017). Figure 3c further shows two Gaussian-fitted peaks (Cr 2p3/2 and Cr 2p1/2) at 576.7 eV and 586.1 eV, respectively, which correspond to Cr³⁺ in ZnCr₂O₄ (Gingasu et al. Reference Gingasu, Mindru, Culita, Patron, Calderon-Moreno, Preda, Oprea, Osiceanu and Morena Pineda2014). In addition, a relatively small Cr 2p3/2 peak at 575.6 eV confirmed the presence of a small amount of Cr₂O₃ on the surface of the solids obtained after thermal treatment (Epling et al. Reference Epling, Hoflund, Hart and Minahan1997). The atomic Zn/Cr ratio was 25:54 on the surface of the sintered sample, which is consistent with the atomic ratio of the ZnCr₂O₄ spinel which was confirmed to be the dominant state of Zn²⁺ in the near-surface region. The O 1s feature of ZnCr₂O₄ has a binding energy of 530.8 eV, which is consistent with the interpretation of the Zn 2p and Cr 2p spectra, indicating that ZnCr₂O₄ oxide is the primary state of Zn and Cr species in the near-surface region.

Fig. 3 (a) XPS survey spectrum, (b) XPS narrow spectrum of Zn 2p, (c) Cr 2p, and (d) O 1s of the products obtained through sintering the mixture of ZnO + Cr₂O₃ at 1000°C for 3 h

TEM images of the ZnCr₂O₄ obtained at different temperatures revealed a heterogeneous morphology of the 700°C treated sample but a more homogeneous morphology for the 1000°C and 1300°C sintered samples (Fig. 4). With the increase in the sintering temperature, the particle sizes became larger and more uniform, due to the melting and fusion of adjacent particles at high temperatures (Gingasu et al. Reference Gingasu, Mindru, Culita, Patron, Calderon-Moreno, Preda, Oprea, Osiceanu and Morena Pineda2014). The EDX spectrum of the 1300°C sintered sample, together with the calculated atomic composition, are summarized in Fig. S1 and Table S1. The corresponding peaks of Zn, Cr, and O were observed with strong signals in the sample, and the elemental composition of Zn and Cr were 28% and 52%, respectively. Therefore, the results of EDX analysis confirmed the successful transformation of Zn and Cr into the ZnCr₂O₄ spinel.

Fig. 4 TEM images of the products obtained after sintering the mixture of ZnO + Cr₂O₃ at (a) 700°C, (b) 1000°C, and (c) 1300°C for 3 h

The Cr K-edge XANES spectra of the samples sintered at 900^oC and 1350^oC, together with those of the reference compounds containing Cr(III) and Cr(VI) (Cr₂O₃ for Cr(III) and CrO₃ and K₂Cr₂O₇ for Cr(VI)) are shown in Fig. 5. The pre-edge feature of Cr(VI) was not observed in the sintered products, indicating that the Cr(III) in the raw materials was not oxidized to Cr(VI) during the thermal treatment processes (Lin & Wang, Reference Lin and Wang2012). As shown in the insert in Fig. 5, the pre-edge peak “C” decreased while the white line peak increased in the sample obtained at the higher temperature (1350^oC). As the pre-edge peak is related to the 1s to 3d quadrupole transitions, the increase of the pre-edge peak intensity can be attributed to the enhancement of the p−d orbital mixing in the tetrahedral structure. Therefore, the increase of the pre-edge peak intensity reflects the increase in the number of Cr atoms occupying the tetrahedral site (Chen et al. Reference Chen, Wu, Cui, Chu, Chen and Wu2013).

Fig. 5 Cr K-edge XANES spectra of products obtained after sintering at 900°C and 1350°C

Leaching Behavior of Zn and Cr from ZnCr₂O₄ Spinel

A prolonged TCLP leaching procedure was conducted to evaluate the stability of Zn and Cr in pure ZnCr₂O₄ spinel, in comparison with the corresponding metal leachability from ZnO and Cr₂O₃. Moreover, the leaching performance of the 700~1300°C-sintered sample mixture was also tested to reflect the stability of the metals in real ceramic products. The changes in concentration of Zn and Cr in the leachates of ZnO, Cr₂O₃, and pure ZnCr₂O₄ spinel, as well as in the sample mixture before and after sintering processes, are shown in Fig. 6. The concentration of Zn in ZnO leachate increased substantially to 1160 mg/L even after 0.75 days of leaching (inset in Fig. 6a), while that value reached 29 mg/L in the leachate of Cr₂O₃ (inset in Fig. 6b). Then, the pH was ~6.4 and 3.2 for the leachates of ZnO and Cr₂O₃, respectively, while the concentration of Zn and Cr remained at 1200 and 30 mg/L, respectively, during the rest of the leaching period. However, for the leachate of ZnCr₂O₄ spinel, a dramatic decrease was detected in Zn (30 times) and Cr (5 times) concentrations compared with the leachates of their metal oxide forms (insets in Fig. 6a and 6b). With prolonged leaching, the concentrations of both metals remained at the initial value even though the pH of the leachate was very low (~3.2) until the end of this leaching experiment (Fig. S2a).

Fig. 6 The concentrations of Zn and Cr in the leachate after sample leaching with leaching periods of 0.75, 5, or 21 days. (a) Zn concentration as ZnO and ZnCr₂O₄, (b) Cr concentration as Cr₂O₃, (c) Zn, and (d) Cr concentrations of the mixtures after sintering at ~700–1300°C

To evaluate further the stability of Zn and Cr in the sintered products, leaching experiments on the raw mixture of ZnO + Cr₂O₃ and the mixture sintered at various temperatures were performed. The amount of Zn leached from the raw mixture (Fig. 6c) reached ~2125 mg/L, but that amount decreased by a factor of three when the mixture was sintered at a relatively low temperature (800°C). Moreover, with further temperature increase, a substantial decrease was observed until reaching ~25 mg/L in the leachates of samples sintered at temperatures ≥1200°C. Proton-metal exchange is the dominant proton depletion process in the acid environment (Snellings, Reference Snellings2015), which results in a very high concentration of Zn in the leachates of the raw mixture and in samples treated at lower temperatures (Fig. 6c). As reflected in the pH value shown in Fig. S2a, the leachate pH was ~6.5 after leaching for 0.75 days. Therefore, the protons were completely consumed by more mobile Zn, which will inhibit the leaching of Cr, resulting in the very low concentrations (nearly zero) in the leachates of the raw mixture and samples sintered at 700°C (Fig. 6d). With the formation of ZnCr₂O₄ spinel, the leachability of Zn was reduced significantly due to its incorporation into the spinel structure. As a result, the extra protons in the solution attacked Cr instead and caused the Cr concentration to increase in the leachates of products sintered at 800–1000°C. With the continuous formation of ZnCr₂O₄ spinel, however, the leachability of Cr also decreased by >3 timeseven in an acidic environment with a pH of ~3.0. Moreover, Zn and Cr concentrations in the leachates of sintered samples were greater (Fig. 6), which further indicates the excellent performance of ZnCr₂O₄ spinel in long-term resistance to acidic attack.

Co-Immobilization of Zn and Cr in Actual Contaminated Soils

The above results confirmed that thermal treatment of a ZnO and Cr₂O₃ mixture successfully incorporated Zn and Cr into the stable ZnCr₂O₄ spinel structure, so the next step was to apply the method to waste brownfield-site soils in which Zn and Cr are both typical metal pollutants (Kumpiene et al. Reference Kumpiene, Lagerkvist and Maurice2008). Results from other studies (Kadir et al. Reference Kadir, Hassan, Salim, Sarani, Ahmad and Rahmat2018; Su et al. Reference Su, Tang, Liao, Kong, Xiao, Shih, Song, Chen and Zhang2018; Tang et al. Reference Tang, Xin, Shih and Wang2018) also gave encouragement that such an approach would be successful in stabilizing the Zn²⁺ and Cr³⁺ ions. Those studies also indicated that the presence of Al, Si, and Fe (oxyhydr)oxides in the soils could further facilitate the stabilization of the heavy-metal pollutants. Although the waste brownfield soil is highly polluted, the Zn and Cr contents are still much lower than those of the major elements contained in the soil, such as Si, Al, and Fe (Table S2). Therefore, even with the successful incorporation of Zn and Cr into the spinel structure, the ZnCr₂O₄ spinel might not be observed clearly by the XRD technique. For this reason, .the soils were spiked with ZnO and Cr₂O₃ to investigate the formation of spinel crystalline structure during thermal treatment of that matrix.

For the Zn- and Cr-enriched soil, the XRD patterns revealed that Zn and Cr incorporated successfully into the ZnCr₂O₄ spinel structure after thermal treatment at 1000°C (Fig. 7a). Besides the existence of the ZnCr₂O₄ as a predominant phase, quartz (SiO₂), as a major component in the soil, was also identified. The Zn leachability of both the sintered and un-sintered AZC samples was measured (Fig. 7b). The concentration of Zn leached from the un-sintered samples reached ~2300 mg/L, but a substantial decrease to 100 mg/L was observed after relatively low-temperature sintering (800°C). With further increase in the sintering temperature, the Zn concentration dropped to ~1 mg/L which is three orders lower than in the raw mixture. Therefore, even in the artificially contaminated soils with relatively large Zn and Cr contents, Zn was stabilized by the formation of ZnCr₂O₄ spinel after the relatively low-temperature thermal treatment.

Fig. 7 (a) XRD pattern of the artificially Zn- and Cr-enriched soils sintered at 1000°C for 3 h, and (b) the Zn concentration in the 18 h leachates of the above soils sintered at temperatures from 700 to 1350°C for 3 h

The leachability of other heavy metals was also decreased dramatically in the brownfield soils after thermal treatment at 1000°C. Concentrations of Zn, Cr, Cu, Cd, Al, Fe, and Si were 2.38, 0.68, 1.39, 0.08 , 15.61, 0.40, 0.49 mg/L, respectively, in the leachates of the un-spiked, un-sintered soils. However, after thermal treatment, the corresponding concentrations were decreased to 0.31, 0.12, 0.16, 0.03, 1.26, 0.03, and 0.28 mg/L, respectively (Fig. 8). As implied by the study of the mechanism of incorporation of ZnO and Cr₂O₃ into the spinel structure, Zn acts as the divalent ions while Cr is trivalent. Therefore, ZnCr₂O₄ spinel will be generated during the sintering process, causing a significant reduction in metal leaching. Moreover, besides Cr(III), other major elemental components such as Al and Fe also exist in the reaction system in the trivalent state; thus enabling the incorporation of other hazardous, such as copper and zinc in the other spinel structures (such as CuAl₂O₄). With the successful stabilization of multiple heavy metals, contaminated brownfield soils can be used beneficially as part-substitution for clay minerals to produce a variety of ceramic products, such as bricks, refractories, and road pavement materials (Shih et al. Reference Shih, White and Leckie2006; Zhou & Keeling Reference Zhou and Keeling2013; Smol et al. Reference Smol, Kulczycka, Henclik, Gorazda and Wzorek2015; Zhou et al. Reference Zhou, Zhao, Chen and He2016).

Fig. 8 Concentrations of Zn, Cr, Cu, Cd, Al, Fe, and Si in the leachates of the brownfield-site soils collected before and after sintering at 1000°C for 3 h. The initial pH value of the leaching liquid was 2.9