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Catalytic Reduction of Congo Red to Low-Toxicity Forms Using a Low-Cost Catalyst Based on Modified Bentonite Material

Published online by Cambridge University Press:  01 January 2024

Mehdi Zahraoui
Affiliation:
Département Génie Des Procédés, Faculté Des Sciences Et Technologies, Université de Relizane, 48000 Relizane, Algeria Laboratoire de Chimie Des Matériaux L.C.M., Université Oran1 Ahmed Ben Bella, BP 1524, El-Mnaouer, 31000 Oran, Algeria
Adel Mokhtar*
Affiliation:
Département Génie Des Procédés, Faculté Des Sciences Et Technologies, Université de Relizane, 48000 Relizane, Algeria Laboratoire de Chimie Des Matériaux L.C.M., Université Oran1 Ahmed Ben Bella, BP 1524, El-Mnaouer, 31000 Oran, Algeria
Zohra Aouali Kebir Medjhouda
Affiliation:
Laboratoire de Chimie Des Matériaux L.C.M., Université Oran1 Ahmed Ben Bella, BP 1524, El-Mnaouer, 31000 Oran, Algeria
Soumia Abdelkrim
Affiliation:
Laboratoire de Chimie Des Matériaux L.C.M., Université Oran1 Ahmed Ben Bella, BP 1524, El-Mnaouer, 31000 Oran, Algeria
Bouhadjar Boukoussa
Affiliation:
Laboratoire de Chimie Des Matériaux L.C.M., Université Oran1 Ahmed Ben Bella, BP 1524, El-Mnaouer, 31000 Oran, Algeria Département de Génie Des Matériaux, Faculté de Chimie, Université des Sciences et de la Technologie Mohamed Boudiaf, BP 1505, El-Mnaouer, 31000 Oran, Algeria
Amal Djelad
Affiliation:
Laboratoire de Chimie Des Matériaux L.C.M., Université Oran1 Ahmed Ben Bella, BP 1524, El-Mnaouer, 31000 Oran, Algeria
Mohammed Abdelkrim Hasnaoui
Affiliation:
Laboratoire de Chimie Des Matériaux L.C.M., Université Oran1 Ahmed Ben Bella, BP 1524, El-Mnaouer, 31000 Oran, Algeria
Mohamed Sassi
Affiliation:
Laboratoire de Chimie Des Matériaux L.C.M., Université Oran1 Ahmed Ben Bella, BP 1524, El-Mnaouer, 31000 Oran, Algeria
Mohamed Abboud
Affiliation:
Catalysis Research Group (CRG), Department of Chemistry, College of Science, King Khalid University, P.O. Box 9004, Abha 61413, Saudi Arabia
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Abstract

The reduction of azo dyes to less toxic and more easily biodegradable amine derivatives is an effective strategy for the treatment of industrial wastewater. The present work aimed to study the reduction reaction of azo dye Congo red (CR) catalyzed by nanoparticles (NPs) of chromium oxides (Cr2O3NPs) immobilized on bentonite in the presence of NaBH4. Cr(III) ions were intercalated using ion exchange reactions to obtain Cr-bentonite, and then the immobilized chromium cations were treated using NaBH4 leading to the formation of Cr2O3NPs-bentonite. The physicochemical properties of the samples were investigated using X-ray diffraction (XRD), scanning electron microscopy/energy dispersive spectroscopy (SEM-EDS), atomic absorption spectrometry (AAS), UV–Visible diffuse reflectance (UV–Vis DR), and Fourier-transform infrared (FTIR) spectroscopy techniques. The results showed the formation of various chromium species, in which the most dominant were chromium oxide nanoparticles, on the bentonite surface with an average particle size between 20 and 35 nm. Line-scan analysis showed a reactive catalytic surface due to the excellent distribution of Cr on the bentonite surfaces. The best-performing catalyst, Cr2O3NPs-bentonite, displayed significant catalytic activity compared to the bentonite and Cr-bentonite materials, with a full reduction time of 630 s and a rate constant, kapp, equal to 0.034 s–1. The resulting products (benzidine and sodium 3, 4-diaminonaphthalene-1-sulfonate) from the catalytic reduction exhibited low toxicity compared to the CR dye; these products are easy to use in chemical synthesis. All results collected from this work indicated that this low-cost catalyst can be exploited to eliminate other dyes from the environment.

Type
Original Paper
Copyright
Copyright © The Author(s), under exclusive licence to The Clay Minerals Society 2023

Introduction

The presence of synthetic dyes in aquatic systems is a serious environmental problem. These toxic substances are used widely in industry where they are often discharged without treatment (Madhav et al., Reference Madhav, Ahamad, Singh and Mishra2018; Krishnan et al., Reference Krishnan, Subbiah, Kalivel and Subramanian2021). Azo dyes (−N=N−) are the most widely used synthetic dyes and constitute the majority of dye production in the world. This type of pollutant has caused severe water pollution which poses a significant threat to human health. In addition to this azo group, they also contain sulfonic (−SO3 ), hydroxyl (−OH), and other electron-withdrawing functional groups, making them less susceptible to degradation. Congo red (CR) belongs to the azo dyes and is abundant in the effluents of the textile and paper industries and has been reported to be extremely carcinogenic and toxic to the environment and to humans (Hudson, Reference Hudson1984). The processing of CR is difficult due to the bulky structure which cannot be degraded easily. Due to the complex nature of textile effluents and the intrinsic properties of this type of dye, therefore, the conventional treatment technologies barely reduce dissolved organic matter and color in textile effluents.

Among the treatment methods, adsorption and catalytic degradation are considered to be the most effective and reliable techniques for the treatment of water containing azo dyes. The adsorption process is characterized by good processing efficiency, ease of use, and relatively low cost; its greatest drawback may be the difficulty in removing contaminants from the adsorbent sample which can saturate its active sites and thus preclude reuse (Vakili et al., Reference Vakili, Deng, Cagnetta, Wang, Meng, Liu and Yu2019). Many toxic dyes can be removed in a short time using catalytic reduction; this results in less toxic products with > 80% conversion even after five cycles of use (Hachemaoui et al., Reference Hachemaoui, Boukoussa, Ismail, Mokhtar, Taha, Iqbal, Hacini, Bengueddach and Hamacha2021a). The use of economical and low-cost catalysts with large surface areas is essential in catalytic reactions and can also reduce the cost of wastewater treatment.

The activity and selectivity of the nanoparticle-based catalysts in the heterogeneous catalysis reaction depend mainly on the metallic particle size (Hachemaoui et al., Reference Hachemaoui, Mokhtar, Ismail, Mohamedi, Iqbal, Taha, Bennabi, Zaoui, Bengueddach and Hamacha2021b; Abdelkrim et al., Reference Abdelkrim, Mokhtar, Djelad, Hachemaoui, Boukoussa and Sassi2022; Asli et al., Reference Asli, Abdelkrim, Zahraoui, Mokhtar, Hachemaoui, Bennabi, Ahmed, Sardi and Boukoussa2022; Mekki et al., Reference Mekki, Hachemaoui, Mokhtar, Issam, Bennabi, Iqbal, Rahmani, Bengueddach and Boukoussa2022). Metal nanoparticles are better for extreme activity due to their various geometric and electronic properties. Synthesis of finely divided metal particles involves the dispersion of the metal catalyst on an inert support. Many materials such as silica, alumina, carbon, and also aluminosilicates such as zeolites and mesoporous materials have been used as supports for the dispersion of the metal particles (Singh et al., Reference Singh, Lee and Na2020; Zhang et al., Reference Zhang, Gao and Yu2022).

Cr(VI) is one of the most harmful metals. Chromium generally exists in its Cr(III) or Cr(VI) state; while Cr(III) is an important essential micronutrient, Cr(VI) is non-essential, harmful to living organisms, and may cause skin problems, lung cancer, kidney and gastric damage, and respiratory tract and eye irritation (Petrović et al., Reference Petrović, Lazarević, Janković-Častvan, Matić, Milivojević, Milošević and Veljović2023). To reduce these problems, this metal can be dispersed on a solid support and, thus, have its toxicity decreased.

Clay minerals are one variety of natural materials suitable for scientific research into heterogeneous catalysis (Cheng et al., Reference Cheng, Song, Ma, Chen, Zhao, Lin and Zhu2008; De León et al., Reference De León, Castiglioni, Bussi and Sergio2008; Li et al., Reference Li, Wu, Dang, Zhu, Li and Wu2011; Kaur & Kishore, Reference Kaur and Kishore2012). In recent years, phyllosilicate minerals have attracted the interest of scientists in numerous disciplines, including catalysis (Joseph et al., Reference Joseph, Vellayan, González, Vicente and Gil2019; Tharmaraj et al., Reference Tharmaraj, Vandarkuzhali, Karthikeyan and Pachamuthu2022), environmental science (Avila et al., Reference Avila, Lick, Comelli and Ruiz2021; Imanipoor et al., Reference Imanipoor, Mohammadi and Dinari2021; Teğin & Saka, Reference Teğin and Saka2021), biology, and human health (Carretero, Reference Carretero2002; Carretero et al., Reference Carretero, Gomes and Tateo2006; Gomes & Silva, Reference Gomes and Silva2007; Abdelkrim et al., Reference Abdelkrim, Mokhtar, Djelad, Bennabi, Souna, Bengueddach and Sassi2020; Mokhtar et al., Reference Mokhtar, Bennabi, Abdelkrim, Sardi, Boukoussa, Souna, Bengueddach and Sassi2020). This interest is generally due to the interesting properties of the clay minerals, including large adsorption capacity, resistance to mechanical forces, large specific surface area, large cation exchange capacity, and swelling in the presence of water (Carretero et al., Reference Carretero, Gomes and Tateo2006). These beneficial properties, combined with their wide availability and low cost (Alexander et al., Reference Alexander, Ahmad Zaini, Surajudeen, Aliyu and Omeiza2019), make them the preferred material for wastewater treatment.

Bentonite is an ore that is widely available and has very large clay content, consisting primarily of montmorillonite (Mnt). It is created by natural weathering of volcanic ash. Its crystal structure comprises an arrangement of aluminosilicate layers each composed of two tetrahedral silica sheets between which is inserted an octahedral aluminum sheet in a 2:1 (tetrahedral-octahedral-tetrahedra, TOT) configuration. An interlayer space containing water and sodium and/or calcium cations separates adjacent layers. These exchangeable cations counterbalance the negative charge of the aluminosilicate layer, giving the Mnt important properties such as cation exchange capacity (CEC), swellability in water, and space to accommodate within it various other inorganic and organic molecules and cations. These properties make Mnt suitable for a variety of applications. In medicine, for example, it is used in agents for sustained drug release (Park et al., Reference Park, Shin, Kim, Kim, Kang, Lee, Kim, Lee and Kim2016; Hosseini et al., Reference Hosseini, Hosseini, Jafari and Taheri2018). Due to its specific nature and non-toxicity, the ingestion of the phyllosilicates (e.g. Mnt), which carry the drug molecule, does not impede the relief of gastrointestinal ailments or the curing of infectious diseases (Jlassi et al., Reference Jlassi, Krupa, Chehimi, Jlassi, Chehimi and Thomas2017). Clay minerals have generated considerable interest in their use as carriers of inorganic compounds and have been confirmed to have a positive impact on the formation and auxiliary stability of metallic nanoparticles. The characteristics described above open many more fields of potential application of these natural materials (Andrades et al., Reference Andrades, Rodríguez-Cruz, Sánchez-Martín and Sánchez-Camazano2004; Ansari Mojarad et al., Reference Ansari Mojarad, Tamjidi and Esmaeili2020).

The present study aimed to develop a simple method to produce a Cr2O3NPs-bentonite composite as a low-cost and eco-friendly catalyst. The hypothesis was that this could be done by the chemical reduction of Cr(VI)-exchanged bentonite. Another objective was to evaluate the catalytic reduction performance and the recyclability of the catalyst.

Experimental

Materials

The natural bentonite was obtained from the Hammam Boughrara deposit in western Algeria. This material has a cation exchange capacity (CEC) of 80 meq/100 g and a chemical composition already described (Korichi et al., Reference Korichi, Elias and Mefti2009). Cr(III) nitrate nonahydrate (Cr(NO3)3, 9H2O, 99%) and sodium tetrahydridoborate (NaBH4, 98%) were purchased from Sigma-Aldrich (St. Louis, Missouri, USA). Congo red dye (C32H22N6Na2O6S2, CAS number of 573–58-0 and MW 699.66 g/mol) was purchased from Merck Co (Darmstadt, Germany). A representation of the Congo red molecule in 3D format as well as the azo groups is shown in Fig. 1.

Fig. 1 Chemical structure and size of the CR molecule

Characterization

The X-ray diffraction (XRD) patterns of the samples were recorded using a Bruker AXS D8 Advance X-ray powder diffractometer (Karlsruhe, Germany) with CuKα radiation from 2 to 80°2θ at a scanning rate of 2°/min. Scanning electron micrographs (SEM) and energy-dispersive X-ray spectroscopy (EDS) were obtained using a Thermo Scientific Prisma E scanning electron microscope (Waltham, Massachusetts, USA). Samples were sputter-coated with either gold (Au) or carbon (C). Cr in the leaching test was measured by atomic absorption mass spectrometry (Analytik Jena GmbH—novAA 400 P, Jena, Germany) using a graphite furnace with a detection range of 10–50 ųg/L. The calibration solution was Cr/Mg/HNO3. Fourier-transform infrared (FTIR) spectra were recorded between 4000 and 500 cm–1 using a JASCO 4100 spectrometer (Jasco, Japan)(). Ultraviolet–Visible absorbance (UV–Vis) spectra were recorded on a Specord 210 Analytik Jena spectrometer with a holmium oxide filter (Jena, Germany).

Preparation of Catalyst

Prior to the intercalation process, the bentonite was first saturated with Na+ using a NaCl solution (Arbaoui & Boucherit, Reference Arbaoui and Boucherit2014; Korichi et al., Reference Korichi, Elias and Mefti2009), which was designed to promote the ion exchange of Cr(III). The saturation process was carried out as follows: 5 g of bentonite was dispersed in deionized water with a minimum resistivity of 18.2 megohm cm and stirred for 30 min at 30°C, then a previously prepared NaCl solution (1 M, 1000 mL) was added to the prepared mixture with vigorous stirring; the new resulting mixture was stirred for 48 h at 30°C, then filtered and washed with deionized water until free of unreacted NaCl. Finally, the Na-saturated solid obtained was dried at 70°C for 72 h.

The dispersion of Cr(III) cations in the interlayer spaces of the Mnt was carried out using an ion-exchange process, and the protocol was as follows: 1.4 g of bentonite was dispersed in deionized water, then the resulting mixture was stirred for 2 h at room temperature (solution A). Cr(III) nitrate solution (100 mL, 0.1 M) was prepared by adjusting the pH to avoid precipitation, and then the solution was added to solution A. After that, the Cr-bentonite material obtained was recovered by filtration, washed thoroughly with distilled water to remove excess unreacted Cr(III) cations, and dried at 70°C for 72 h. The amount of Cr-bentonite material was treated with NaBH4 solution (100 mL, 4 M). The mixture was stirred for 2 h; the final Cr2O3NPs-bentonite product was filtered, washed, and dried overnight.

Catalytic Application

Bentonite, Cr-bentonite, and Cr2O3NPs-bentonite were evaluated first in order to choose the best catalyst from among them. The catalytic reduction of CR dye in the presence of NaBH4 was carried out under the following conditions: 0.034 g of each catalyst, 0.05 M NaBH4, and 0.06 mM of CR, no solution pH adjustment was made, and the reduction of CR dye was measured in situ by UV–Vis spectroscopy. Firstly, 2.5 mL of CR dye solution was added to 1.5 mL of freshly prepared NaBH4. This solution was transferred to a quartz cuvette to which an amount of catalyst was also added. This system was then loaded into the UV–Vis spectrophotometer and the program was set to scan the sample every 30 s. Afterward, two parameters that affected the catalytic reduction, namely the dose of the catalyst (0.014–0.034 g) and the initial dye concentration (0.06–0.12 mM) were assessed. An adsorption test (dye + catalyst) and a test without catalyst (NaBH4 + dye) were also realized. The kinetics of catalytic dye reduction was investigated by applying the pseudo-first order rate law (Eq. 1 and 2). The percentage degradation of CR dye was also established by using Eq. 3.

(1) d A t dt = - k app A t
(2) ln A t A 0 = - k app t

where kapp (s−1) is the rate constant, A t is the absorbance at time t, and A 0 is the initial absorbance of the CR dye.

(3) Percentage of conversion of CR ( % ) = A 0 - A t A 0 × 100

Statistical Analysis

The residual sum of squares (RSS, Eq. 4) measures the accuracy of a regression model. The smaller the residual sum of squares, the better the model fits the data; the greater the residual sum of squares, the less well the model fits the data (Marquardt, Reference Marquardt1963).

(4) RSS = i = 1 n ( y i - fx i ) 2

Results and Discussion

Characterization of Samples

XRD

The structural properties of all prepared samples were examined by XRD analysis. The XRD patterns of bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples (Fig. 2) clearly showed a crystalline structure similar to that of pure Mnt, as described in previous studies, which was confirmed by the presence of reflections (001), (100), (110), and (210) corresponding to Mnt (Cheng et al., Reference Cheng, Zhang, Xie, Chen and Li2013). The XRD pattern exhibited the characteristics (001) peak of Mnt at 6.437°2θ, d 001 = 1.372 nm. In addition, the diffraction peaks related to quartz, illite, calcite, and K-feldspar impurities were also observed. After the ion-exchange process, the (001) reflection shifted to a lower angle, giving a d-spacing of 1.423 nm, which was attributed to the species with a smaller ionic radius being replaced by the species with a larger ionic radius, indicating successful intercalation of Cr(III) cations in the interlayer spaces of montmorillonite. After the chemical treatment using NaBH4 the d-spacing was then increased to 1.538 nm. This was probably due to the agglomeration of chromium oxide species on the surface of the bentonite. The characteristic peaks for chromium oxide (at 24.73, 32.62, 35.30, 39.74, 41.64, 45.35, 50.28, 54.89, 59.16, and 73.27°2θ, corresponding to the (012), (104), (110), (113), (202), (024), (116), (214), (300), and (101) planes (Almontasser & Parveen, Reference Almontasser and Parveen2020; Khan et al., Reference Khan, Shahid, Hanif, Almoallim, Alharbi and Sellami2021), respectively, were observed with low intensities, indicating that the Cr2O3NPs were highly dispersed on the bentonite support. This result implies the formation of the rhombohedral structure of chromium in the interlayer spaces of bentonite. By using the Scherrer equation (Eq. 5) (Patterson, Reference Patterson1939), the average particle diameter was calculated and found to be between 35 and 40 nm.

(5) The mean size of particles ( τ ) = K λ β cos θ

where τ is the crystallite size (nm); K = 0.9, the shape factor; λ (= 0.154060 nm), the wavelength of Cu-Kα radiation; β, the integral breadth of the most intense peak (FWHM); and θ, the diffraction angle.

Fig. 2 XRD patterns of bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples

SEM and EDS

SEM–EDS analysis was used to study the surface morphology and the elemental constituents of the samples. The SEM images of Cr-bentonite and Cr2O3NPs-bentonite samples (Figs. 3a,b and 4a,b, respectively) confirmed the conservation of the structure of the Mnt even after the ion-exchange process and the chemical treatment with NaBH4. All micrographs showed the same morphology, which corresponds to the presence of aggregates of ancillary minerals in the bentonite (supplementary information Fig. S1); these are heterogeneous in size and have irregularly shaped cavities, similar results to those found by Cheng et al. (Reference Cheng, Zhang, Xie, Chen and Li2013).

Fig. 3 SEM–EDS analysis of Cr-bentonite: a-b SEM images, c EDS spectrum, and d SEM–EDS element mapping images

Fig.4 SEM–EDS analysis of Cr2O3NPs-bentonite: a-b SEM images c EDS spectrum, and d SEM–EDS element mapping images

The EDS spectra of Cr-bentonite and Cr2O3NPs-bentonite (Figs. 3c and 4c, respectively) revealed brighter areas, indicating the presence of Cr (Ngah et al., Reference Ngah, Teong, Toh and Hanafiah2012). The brighter areas are because of the better electric conduction properties of chromium compared to the Mnt itself. O, Na, Al, and Si were found in both Cr-bentonite and Cr2O3NPs-bentonite, which is not surprising because these are the major components of bentonite. The weight percentages of these elements in Cr-bentonite were O (46.98%), Na (0.69%), Al (10.88%), Si (37.09%), and Cr (4.36%) (Fig. 3, embedded table). For the Cr2O3NPs-bentonite, the respective weight percentages were O (43.53%), Na (7.26%), Al (9.05%), Si (33.76%), and Cr (6.40%) (Fig. 4). The increase in Na weight was due to chemical treatment with NaBH4, and the increase in Cr was due to the transformation of Cr(III) to chromium oxide nanoparticles which were dispersed homogeneously on the bentonite surfaces. In addition, the peaks situated at binding energies of 0.5, 5.4, and 5.9 eV indicated the existence of diverse chromium species. Following the element map scan (Figs. 3d and 4d), Cr was clearly intercalated homogeneously on the bentonite. EDS line scan analysis (Fig. 5) was carried out in order to examine the elemental distribution on the Cr-bentonite surfaces; it was distributed homogeneously. That sample thus provided a well dispersed Cr oxide system with a highly reactive catalytic surface. Cr in the Cr2O3NPs-bentonite (Fig. 6) was, therefore, uniformly and homogeneously distributed across the whole sample surface and produced a catalytic surface with uniform, active sites.

Fig. 5 SEM–EDS analysis of Cr-bentonite: a-b line scans of elements and c distribution of Cr

Fig. 6 SEM image and corresponding EDS line scan along the yellow line of the Cr2O3NPs-bentonite surface

UV–Vis DR

UV–Vis DR spectroscopy was used to identify the chemical environment and coordination states (Fig. 7) and a large characteristic band in the region of 200–365 nm was revealed and attributed to Al–O and Si–O bonding in the Mnt layers. UV–Vis spectra of the modified Cr-bentonite and Cr2O3NPs-bentonite samples indicated the presence of two absorption peaks at 413 and 596 nm, which can be attributed to the presence of several Cr species. In addition, the peak intensity at 314 nm of Cr2O3NPs-bentonite was much greater than for the Cr-bentonite. This was due to the transformation of Cr ions to chromium oxide nanoparticles (Ahmad et al., Reference Ahmad, Shamim, Mahmood, Mahmood and Khan2018). In addition, deconvolution of the UV–Vis spectra of the Cr2O3NPs-bentonite (Fig. S2) confirmed the presence of the 4A2g4T1g transition of the six-coordinate geometry at 413 nm and the 4A2g4T2g transition of chromium ions in an octahedral environment at 596 nm (Liang et al., Reference Liang, Zhang, Luo, Luo, Li, Xu and Zhang2014, Reference Liang, Zhang, Luo, Liu, Bai, Xu and Zhang2015).

Fig. 7 UV–Vis DR spectra of bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples

The CR dye also was characterized by UV–Vis spectroscopy and gave characteristic absorption bands of the conjugation throughout the structure and of the azo bond at 492 and 340 nm. Possible reduction products include amino derivatives which have absorption peaks around 284 nm.

FTIR

The FTIR spectrum of bentonite (Fig. 8) is very similar to that of Mnt, as would be expected from the large proportion of Mnt in bentonite (Hayati‐Ashtiani, Reference Hayati-Ashtiani2011; Ikhtiyarova et al., Reference Ikhtiyarova, Özcan, Gök and Özcan2012). The vibration band observed at 3622 cm–1 was attributed to the Al–OH stretching of smectites with a large amount of Al in the octahedral sheet. The broad band observed at 3378 cm–1 was attributed to intercalated water molecules linked through hydrogen bonds to the terminal silanol groups. The band at 1400 cm–1 was attributed to the stretching and bending vibrations of physisorbed water (Hayati‐Ashtiani, Reference Hayati-Ashtiani2011).The band at 985 cm–1 was attributed to the Si−O stretching vibrations (Madejová & Komadel, Reference Madejová and Komadel2001); the band at 610 cm−1 can be attributed to the bending vibration of the Al−O−Si groups (Aroke et al., Reference Aroke, Abdulkarim and Ogubunka2013; Madejová & Komadel, Reference Madejová and Komadel2001). The modified materials, Cr-bentonite and Cr2O3NPs-bentonite, displayed FTIR spectra that differed in terms of the intensity of the main band as well as the presence of new bands in the latter. The FTIR spectrum of Cr-bentonite showed a decrease in the intensity of the band at 1600 cm–1 attributed to the intercalated and physisorbed water molecules, which suggests that the intercalation takes place through an ion-exchange reaction between the Cr(III) ions and the interlayer hydrated sodium cations, thus causing the dehydration of the material obtained after intercalation. The FTIR spectrum of Cr2O3NPs-bentonite contained two new bands at 553 and 600 cm–1 which were attributed to M−O (Cr−O) stretching (Madi et al., Reference Madi, Tabbal, Christidis, Isber, Nsouli and Zahraman2007).

Fig. 8 FTIR spectra of bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples

Catalytic Study: Selecting the Best Catalyst

Bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples were evaluated as catalysts for CR dye reduction in the presence of NaBH4 as a reducing agent. The respective UV–Vis spectra of the reactions of CR (Fig. 9a,b,c) revealed that the characteristic absorption band of CR at 492 nm was decreased after contact with each catalyst sample. The reduction of CR was incomplete in the presence of bentonite and Cr-bentonite, however, whereas in the presence of Cr2O3NPs-bentonite, the reduction reaction was completed after 630 s of contact time. Plots of ln(A t /A 0) as a function of reaction time and the catalytic reaction time vs CR dye conversion are given in Figs. 10a and b, respectively. By obtaining UV–Vis spectra of the reaction mixtures at different time intervals, the absorbance at any given wavelength can be plotted vs time. Plotting the change in absorbance with time at a wavelength of λmax = 492 nm, using the form ln(A t /A 0) (Fig. 10a), showed that the absorbance of CR dye decreased with time, indicating that the reduction reaction was on-going. The reaction was incomplete in the presence of bentonite and Cr-bentonite, however, but reached 87.85% of completion after 630 s in the presence of Cr2O3NPs-bentonite (Fig. 10b). The Cr2O3NPs-bentonite catalyst acted as a charge transfer surface for NaBH4 during the CR reduction reaction, and the reaction became kinetically feasible when the dye molecules were deposited on the Cr2O3NPs-bentonite surface. The presence of chromium nanoparticles facilitated the electron transfer that brought about the catalytic reduction of CR dye; the Cr nanoparticles efficiently mediated electron transfer from BH4 to azo bonds (Jana & De, Reference Jana and De2012). The plot of –ln(A 492) vs time (Fig. 10c) demonstrated that the reaction passed through an initial induction period of ~ 100 s during which reagent diffusion was occurring (Benali et al., Reference Benali, Boukoussa, Ismail, Hachemaoui, Iqbal, Taha, Cherifi and Mokhtar2021). After this lag time, the plot became linear and confirmed that the reaction followed a pseudo-first order rate law. The rate constant and regression coefficient were 0.0015 s−1 and 0.99, respectively (Table 1). The presence of chromium oxide nanoparticles played an important role in improving the catalytic reduction of CR dye, and thus the most efficient catalyst was identified as Cr2O3NPs-bentonite, which then was chosen for the rest of this study.

Fig. 9 Time-dependent UV–Vis spectra of CR solution during the catalytic reaction of: a bentonite, b Cr-bentonite, and c Cr2O3NPs-bentonite

Fig. 10 Study of catalytic reduction of CR dye using bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples in the presence of NaBH4. a Plot of ln(A t /A 0) as a function of reaction time for CR dye reduction; b reaction time and CR dye conversion; and c pseudo-first order plot of –ln(A 492) (absorbance at 492 nm) vs reaction time, t

Table 1 Parameters of the reduction reaction of CR dye

R2 coefficient of determination

A potential hazard from using a Cr-based catalyst is the leaching of Cr ions into the reaction medium. Leaching tests revealed (Fig. S3) that ~1.1 mg Cr/L was leached from Cr-bentonite whereas only 0.23 mg Cr/L was leached from Cr2O3NPs-bentonite.

Variables Affecting the Catalytic Reduction of CR Dye

Firstly, to confirm that both the reductant (NaBH4) and the heterogeneous catalyst (Cr2O3NPs-bentonite) were necessary for the CR reduction reaction to occur, the UV–Vis absorbance of CR at λmax = 492 nm was measured with increasing contact time with the blank (CR dye + NaBH4) and with catalyst + CR dye (Figs. 11a and b, respectively). Changes in absorbance after as much as 990 s in the presence of the catalyst, but in the absence of the reducing agent, were small (Fig. 11b), thus confirming that little reduction reaction occurred without the reductant. The blank test (Fig. 11a), moreover, revealed that NaBH4 (0.05 M) could achieve only a negligible amount of degradation without the catalyst. Hence, the CR dye reduction is clearly governed by a heterogeneous catalytic reaction (Abdelkrim et al., Reference Abdelkrim, Mokhtar, Djelad, Hachemaoui, Boukoussa and Sassi2022; Asli et al., Reference Asli, Abdelkrim, Zahraoui, Mokhtar, Hachemaoui, Bennabi, Ahmed, Sardi and Boukoussa2022).

Fig. 11 Study of catalytic reduction of CR dye using three masses (0.014, 0.024, and 0.034 g) of Cr2O3NPs-bentonite catalyst. a Blank test (NaBH4 + CR dye), b adsorption test (catalyst + CR dye), c plot of ln(A t /A 0) as a function of reaction time for CR dye reduction, and d correlation of the dose of the catalyst with the reaction time and the conversion of CR dye

The effect of Cr2O3NPs-bentonite catalyst dose on CR dye degradation was also investigated (Fig. 11c,d). Three masses of Cr2O3NPs-bentonite catalyst (0.014, 0.024, and 0.034 g) were used in order to optimize the catalyst dose for CR dye reduction. The plot of ln(A t /A 0) as a function of reaction time for CR dye reduction allowed the dose of the catalyst to be correlated with the reaction time and the conversion of the CR dye. The reduction of CR dye neared completion only in the presence 0.034 g of catalyst compared to the other doses (Fig. 11d). The reduction reaction rate tended to increase with increasing catalyst dose (Fig. 11c); the conversion of dye was also greater for 0.034 g of catalyst dose with a conversion of 87.98% (Fig. 11d). The high catalyst dose provides an abundance of surface-charged Cr2O3NPs and, consequently, generates a greater potential for electron transfer and reduces the time required for CR dye reduction.

Two initial dye concentrations (0.06 and 0.12 mM) were also studied to evaluate the performance of the Cr2O3NPs-bentonite catalyst. A plot of ln(A t /A 0) as a function of contact time (Fig. 12) found that, with a CR concentration of 0.06 mM, the reduction reaction rate was rapid, yielding a total conversion of 87.85% in 630 s, giving a rate constant of 0.034 s–1. When the concentration was 0.12 mM, the reduction reaction took longer and dye conversion was less complete, with a calculated rate constant of 6.76 × 10–4 s–1. With a low dye concentration, the reaction sites on the catalyst are less saturated than when the dye concentration is greater. The greater concentration thus impedes the rate and extent of the conversion reaction.

Fig. 12 Change in absorbance of CR with time during catalytic reduction using two initial dye concentrations (0.06 and 0.12 mM)

Plausible Mechanism

A plausible mechanism for the catalytic reduction of CR dye in the presence of NaBH4 is presented in Fig. 13a. The catalytic reaction can reduce the toxicity of CR by converting it to less toxic products. According to this mechanism, in the presence of the catalyst the reducing agent NaBH4 and the dye molecule are adsorbed on the surface of the solid. Dissociation of the reducing agent to tetrahydroborate ions (BH4) in the waste solution donates an electron to the catalyst. Then the reduction of water yields hydrogen (H2), which is a key step for the generation of active hydrogen species at the surface of the catalyst (Bakr et al., Reference Bakr, El-Attar and Salem2019). The azo group −N=N− goes through an addition reaction of hydrogen atoms to give a hydrogenated azo intermediate. Then it undergoes further hydrogenation, followed by breaking of the −NH −NH− bond to generate amine derivatives (Naseem et al., Reference Naseem, Farooqi, Begum and Irfan2018; Benmaati et al., Reference Benmaati, Boukoussa, Hadjadj Aoul, Hachemaoui, Kerbadou, Habib Zahmani and Hacini2022), which are less toxic than azo groups.

Fig. 13 a Plausible mechanism for the reduction of CR dye and f the time-dependent UV–Vis spectra for the reduction of CR dye using Cr2O3NPs-bentonite

Progress of the reduction reaction was followed by means of UV–Vis until the band at 492 nm disappeared (Fig. 13b). The results showed that the characteristic CR absorption bands at 492 and 340 nm gradually decreased and a new peak at 284 nm appeared, which is characteristic of the amino derivatives (benzidine and sodium 3, 4-diaminonaphthalene-1-sulfonate) resulting from the reduction products.

Comparison with the Literature

A comparative study (Table 2) of the catalytic activities of various catalysts reported in the literature for the reduction of the CR dye found that most catalysts are based on noble and/or expensive metals, either alone or on supporting materials. In the present study, the supporting material was bentonite, a natural substance that is less expensive than the others listed in Table 2. The Cr2O3NPs-bentonite catalyst has a greater rate constant than other catalysts; this means that its catalytic activity is also greater and with a shorter conversion time. Due to the rapid reduction that it promotes, Cr2O3NPs-bentonite can be considered to be an effective catalyst for the reduction of environmental pollutants in water.

Table 2 Comparisons of the catalytic activities of various catalysts with Cr2O3NPs-bentonite for the reduction of CR dye

Conclusions

In the present study, the catalytic behavior of low-cost Cr bentonite materials was investigated with respect to the reduction of CR dye. Cr(III) was intercalated into the Mnt layers of the bentonite to obtain Cr-bentonite; it was then treated with NaBH4 to obtain Cr2O3NPs-bentonite. Various characterization techniques were applied to verify the presence of chromium nanoparticles. Leaching tests revealed that ~ 1.1 mg Cr/L was leached from Cr-bentonite whereas ~ 0.23 mg Cr/L was leached from Cr2O3NPs-bentonite. The catalytic reduction behavior of Cr2O3NPs-bentonite was far superior to that of either Cr-bentonite or bentonite alone, in terms of its ability to eliminate 87.85% of the CR dye in 630 s with a rate constant, kapp, of 0.034 s–1.

Supplementary Information

The online version contains supplementary material available at https://doi.org/10.1007/s42860-023-00226-8.

Acknowledgements

The authors acknowledge the Deanship of Scientific Research at King Khalid University for funding this work through a research project number RGP.2/226/43.

Data Availability

All the data and materials for this study are available herein.

Declarations

Ethics Approval and Consent to Participate

Not applicable.

Consent for Publication

Not applicable.

Conflict of Interest

The authors declare that there is no conflict of interest.

Footnotes

Associate Editor: Jun Kawamata

Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.

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Figure 0

Fig. 1 Chemical structure and size of the CR molecule

Figure 1

Fig. 2 XRD patterns of bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples

Figure 2

Fig. 3 SEM–EDS analysis of Cr-bentonite: a-b SEM images, c EDS spectrum, and d SEM–EDS element mapping images

Figure 3

Fig.4 SEM–EDS analysis of Cr2O3NPs-bentonite: a-b SEM images c EDS spectrum, and d SEM–EDS element mapping images

Figure 4

Fig. 5 SEM–EDS analysis of Cr-bentonite: a-b line scans of elements and c distribution of Cr

Figure 5

Fig. 6 SEM image and corresponding EDS line scan along the yellow line of the Cr2O3NPs-bentonite surface

Figure 6

Fig. 7 UV–Vis DR spectra of bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples

Figure 7

Fig. 8 FTIR spectra of bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples

Figure 8

Fig. 9 Time-dependent UV–Vis spectra of CR solution during the catalytic reaction of: a bentonite, b Cr-bentonite, and c Cr2O3NPs-bentonite

Figure 9

Fig. 10 Study of catalytic reduction of CR dye using bentonite, Cr-bentonite, and Cr2O3NPs-bentonite samples in the presence of NaBH4. a Plot of ln(At/A0) as a function of reaction time for CR dye reduction; b reaction time and CR dye conversion; and c pseudo-first order plot of –ln(A492) (absorbance at 492 nm) vs reaction time, t

Figure 10

Table 1 Parameters of the reduction reaction of CR dye

Figure 11

Fig. 11 Study of catalytic reduction of CR dye using three masses (0.014, 0.024, and 0.034 g) of Cr2O3NPs-bentonite catalyst. a Blank test (NaBH4 + CR dye), b adsorption test (catalyst + CR dye), c plot of ln(At/A0) as a function of reaction time for CR dye reduction, and d correlation of the dose of the catalyst with the reaction time and the conversion of CR dye

Figure 12

Fig. 12 Change in absorbance of CR with time during catalytic reduction using two initial dye concentrations (0.06 and 0.12 mM)

Figure 13

Fig. 13 a Plausible mechanism for the reduction of CR dye and f the time-dependent UV–Vis spectra for the reduction of CR dye using Cr2O3NPs-bentonite

Figure 14

Table 2 Comparisons of the catalytic activities of various catalysts with Cr2O3NPs-bentonite for the reduction of CR dye

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