Layered Rare-Earth Hydroxide Unilameller Nanosheets: Synthesis, Characterization, and Adsorption

Omwoma, Solomon; Stephen Odongo, Adongo; Otieno, Zablon; Lagat, Silas; Lalah, Joseph Owuor

doi:https://doi.org/10.1155/2020/8923871

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Abstract Introduction Materials and Methods Results and Discussion Conclusions Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2020 | Article ID 8923871 | https://doi.org/10.1155/2020/8923871

Layered Rare-Earth Hydroxide Unilameller Nanosheets: Synthesis, Characterization, and Adsorption

Solomon Omwoma,¹Adongo Stephen Odongo,¹Zablon Otieno,¹Silas Lagat,¹and Joseph Owuor Lalah²

Academic Editor: Philippe Trens

Received08 May 2019

Revised07 Nov 2019

Accepted16 Nov 2019

Published28 Jan 2020

Abstract

Unilameller nanosheets with a lateral dimension of one nanometer have been isolated from a colloidal solution of europium-containing layered rare-earth hydroxide (LRH) material by the flocculation method. The nanosheets were achieved by changing pH of the colloidal solution from 6.7 to 11.5. The resultant flocculated nanosheets show high efficiency in sorption of fluoride anions from aqueous media (40 mmol/g), providing a potentially useful sorbent material for water purification technology. The sorbent material is demonstrated to be reusable for at least ten times without a significant loss of adsorption efficiency. And the results fit the Langmuir adsorption curve, indicating the chemisorption nature of the nanosheets. Most importantly, the isolated nanosheets are expected to widen the applicability and flexibility in material synthesis using two-dimensional nanomaterials.

1. Introduction

Synthesis of building blocks used in advancement of material chemistry is highly affected by size, surface, shape, defect properties, and anisotropy. Anisotropy is determined by geometry and structure of self-assembled materials and is sometimes difficult to achieve in nanomaterials. However, there has been progress in synthesis of materials such as the functional oxide nanosheets and exfoliated layered double hydroxides (LDHs) [1–4]. The synthesized nanosheets have been shown to display robust chemical-physical properties such as lateral dimensions of less than 10 nm, high adsorption rates, great catalysts, and high dispersion rates in solvents that make them useful building units in the manufacture of nanodevices [5–7].

Only LDH nanosheets exhibit a positive charge, whereas all the other nanosheets are negatively charged [7]. Delamination of LDH nanosheets has been reported to occur mainly in formamide solution [8, 9]. It is noted that delamination of LDHs in aqueous media is difficult due to the high charge density of the LDHs layers and the high anion contents that result in strong interlayer electrostatic interactions between the sheets and the extensive interlamellar hydrogen bonding networks, which lead to a tight stacking of the lamellae [2, 10, 11]. This limits the use of these building units especially for aqueous reactions.

Layered rare-Earth hydroxides (LRHs) have a general formula of Ln₈(OH)₂₀(A^m−)_4/m·nH₂O (Ln = rare-earth ions; A = intercalated anions). LRHs with one type of Ln³⁺ cations occupying the octahedral position on the layers can be easily delaminated into individual nanosheets in aqueous media [12–17], which is in good contrast to that of LDHs. Moreover, the sonication of LRHs in the aqueous medium results in the formation of a colloidal solution, which consists of a number of unilameller layers of the positively charged nanosheets of [Ln₈(OH)₂₀·nH₂O]⁴⁺ [12–14]. These lamellar positively charged nanosheets are vital building units for the synthesis of LRH-containing functional materials due to their positively charged surfaces. However, these unilameller nanosheets have not been isolated so as to extend the novel applicability of positively charged nanosheets.

Herein, a simple new method of isolating the unilameller nanosheets is reported. Stable unilameller nanosheets were isolated by changing the pH of the colloidal solution from 6.5 to 11.5. The flocculated unilameller nanosheets show good performance for fluoride sorption from aqueous media, providing a potentially useful sorbent material for water purification technology. And we demonstrate the recyclability of this material in fluoride separation from the aqueous medium.

It is important to note that fluoride has detrimental health effects to aquatic life and humans such as cancer, dental fluorosis, bone resorption, endocrine disruption, mutations, and brain damage. [18]. Hence, industries that use fluoride in their processes ought to separate it from wastewater before disposal of the water to aquatic systems.

In addition, although nanosorbents present a great potential in advancing water and wastewater treatment efficiency, most of the nanosorbents reported so far generate secondary wastes which are equally hazardous to the environment [19]. As such, development of recyclable nanosorbents is a big step forward in wastewater treatment efficiency.

2. Materials and Methods

2.1. Chemical Materials

Analytically pure KOH, NaOH, Eu₂O₃, HCl, NaF, KBr, lacmoid, ethanol, and methanol were purchased from Alfa Aesar and used without further purification.

2.2. Preparation of Wet LEuH-Cl

Eu-containing layered rare-Earth hydroxides (Eu₂(OH)₅Cl·nH₂O) (LEuH-Cl) were synthesized and characterized according to literature methods [12]. In brief, 0.1 M KOH solution was added to 0.05 M EuCl₃·6H₂O solution with stirring at 24°C. The resultant mixture was heated to 60°C for 12 h and thereafter refluxed for 24 h as with magnetic stirring. The resultant slurry was washed with deionized water three times in a centrifuge. The solid sample was labeled as wet LEuH-Cl.

2.3. Flocculation

The delamination of fresh prepared wet LEuH-Cl aggregate material was achieved by sonication (3 min @ 100 W) to obtain an aqueous colloidal solution. Sonication beyond these specifications is noted to result into broken delaminated nanosheets. The pH of the aqueous colloidal solution was adjusted from 6.5 to 11.5 using 1 M NaOH solution that led to flocculation of unilameller LEuH nanosheets (LEuH-flocs). The contents were centrifuged at 2000 rpm, and the residue was washed with distilled water four times before a final wash with acetone followed by vacuum drying at 40°C.

2.4. Characterization

The OH content of solid samples was determined titrimetrically by neutralization backtitration after dissolution of the samples in a 0.1 N standard H₂SO₄. Measurements of diffraction patterns of the 40°C dried samples were achieved using a Rigaku XRD diffractometer machine (6000) conditioned at 30 mA, 40 kV, Cu-Ka (λ = 0.154 nm), and with a scan step of 0.01° measured between 3° and 70°. Surface morphology was observed using a SEM (Zeiss Supra 55) machine simultaneously connected to an EDX detector. In addition, atomic forces were determined using a Bruker AFM machine (A3A) in order to determine lateral dimensions of nanosheets isolated. Cross-sectional transverse morphological study was done using a HRTEM machine (Hitachi H-800). High sensitivity elemental analysis in aqueous solutions was performed using ICP-AES machine (ICPS-7500). Solid samples were first digested using aqua regia solutions before ICP-AES analysis. The pore volumes and specific surface area studies for solid samples were done using BET and BJH methods with Quantachrome Autosorb1C VP machine. Before such analyses were done, the solid samples were first degassed at 100°C for 6 hrs.

2.5. Adsorption Experiments

The efficiency of fluoride sorption by LEuH-flocs nanosheets was compared to the sorption efficiency of LEuH-Cl aggregates. To a known concentration of fluoride ions in aqueous media, 0.4 g of test sample was introduced and then the test solution was kept stirring for 1 hour. After that, the nanocomposites were centrifuged down and the supernatant solution was tested for fluoride concentration colorimetrically [20]. The pelleted sample was dried and calcined at 500°C for 24 hours to remove the adsorbed fluoride, and the material was reconstituted in a NaCl solution to regenerate the LEuH-Cl material through the “memory effect” method of hydrotalcites [7]. Direct adsorption of the fluoride ions by the calcined LEuH-flocs was also determined.

2.6. Kinetic Studies

2.6.1. Determination of Adsorption Rate and Equilibrium

Ten samples of fluoride ions dissolved in deionized water (100 ppm) were treated with 0.2 g of LEuH-flocs for 0, 1, 2, 3, 4, 5, 6, 8, 10, and 15 minutes. After each experiment, the LEuH-flocs were separated and the resultant supernatant was tested for fluoride concentration. A similar experiment was repeated for the LEuH-Cl aggregate material.

2.6.2. Adsorption Isotherms

The test samples (0.2 g) were stirred with 50 ml solutions having different concentrations (1, 5, 10, 20, 50, 100, 200, 300, 400, 500, and 1000 ppm) of fluoride anions for 30 minutes to insure equilibrium. The nanocomposites were centrifuged, and the supernatant was tested for fluoride concentration. The amount of fluoride up-taken per gram of the LEuH-flocs (q) was determined according to the following equation, where C₀ is the initial fluoride concentration, C is the concentration of the equilibrated final solution, V is the volume of the aqueous phase, and m is the mass of the adsorbent in the system:

3. Results and Discussion

3.1. Characterization of the Nanocomposite Materials

Adjusting the pH of a colloidal solution, sonicated from freshly prepared wet LEuH-Cl aggregates, from pH = 6.5 to pH = 11.5 resulted into flocculation of unilameller LEuH nanosheets (LEuH-flocs) (Figure 1). During the pH adjustment experiments, there was no observable change between pH∼4.5 and ∼9.5. However, below pH∼4.5, the nanosheets decomposed to individual elements. Chemical analysis of LEuH-flocs reveal an elemental composition of Eu₈(OH)₂₀(CO₃)_0.67(H₂O)_4.4Cl_3.15, which is simplified as [Eu₈(OH)₂₀(H₂O)_4.4]Cl₄. The composition resembles that of the starting material (LEuH-Cl aggregates).

SEM images of both LEuH-flocs nanosheets and LEuH-Cl aggregates show similarity in plate-like morphology with the former exhibiting unilameller platelets, while the latter is organized in layers ranging from 20 nm to 65 nm (Figure 2). Energy dispersive X-ray spectroscopy (EDX) images provide further evidence of composition similarity (Figure 2). However, TEM images show the unilameller nature of the LEuH-flocs (Figure 2).

(a)

(b)

(c)

(d)

The unilameller character of the LEuH-flocs can also be clearly distinguished from the layered character of LEuH-Cl aggregates by HRTEM images (Figure 3). And the selected area electron diffraction (SAED) patterns of LEuH-flocs are much clearer than that of LEuH-Cl aggregates, indicating the high crystallinity of the LEuH-flocs nanosheets (Figure 3). Despite the crystallinity differences, it is evidently clear from the SAED patterns that atomic arrangement remains the same in both samples (Figure 3). The atoms are arranged in a pseudohexagonal symmetry with a unit fundamental cell of a_f = 3.7 Å. It can be calculated that d₁₀₀ = 2√3a_f = 12.8 Å and d₀₁₀ = 2a_f = 7.4 Å. These particular atomic distances are further verified by XRD diffraction patterns shown in Figure 4.

(a)

(b)

(c)

The LEuH-Cl aggregate sample exhibits XRD patterns that can be indexed as a single orthorhombic unit cell with lattice parameters of a = 12.90 Å (d₁₀₀), b = 7.52 Å (d₀₁₀), and c = 8.63 Å (d₀₀₁). These values clearly correspond to the calculated values from SAED patterns in Figure 3. Since the LEuH-flocs exist as unilameller layers, it is almost impossible to distinguish the d₁₀₀and d₀₁₀ reflections in the XRD patterns; however, the d₀₀₁ = 7.6 Å reflection is clear with a very high intensity indicating the nanosheets to lie on their c plane. Nevertheless, there is no restacking because no d_00l harmonics were observed. And it is worth noting that the results of LEuH-Cl aggregates are in good agreement with literature [17].

The AFM images of a colloidal solution for both LEuH-flocs and LEuH-Cl aggregates dispersed on wafer plates show the width of LEuH-flocs to be approximately 1 nm, while LEuH aggregates are approximately 26 nm (Figure 5). Dispersion of the LEuH-flocs nanosheets in water at pH = 7 results into a colloidal solution indicating the nanosheets to maintain both their nanoscale size and their charge (Figure 5(c)).

FTIR vibrations show an intense absorption band at 3494 cm⁻¹ attributed to O-H bond, , stretching in both the LEuH-flocs nanosheets and LEuH-Cl aggregates (Figure 6). The vibration band at 1634 cm⁻¹ is due to the bending mode of both surface and interlayer water (see Figure 7 for water contents). Two sharp bands at 1511 and 1454 cm⁻¹ in LEuH-Cl aggregates are attributed to vibrations in a layered structure [13]. However, there exists a shift in these CO vibrations and a decrease in sharpness which is indicative of the lack of stacking in the LEuH-flocs nanosheets [13]. Two shoulder peaks at 848 and 818 cm⁻¹ are due to interlayer chloride anions, while the bands at 638 and 535 cm⁻¹ are attributed to Eu-O stretching. In addition, the O-C-O bending mode may have shifted from 526 to 535 cm⁻¹ due to lack of stacking. Furthermore, the band at 1374 cm⁻¹ in LEuH-flocs and LEuH-flocs + fluoride might arise from adsorbed .

Thermogravimetric analysis of LEuH-flocs and LEuH-Cl aggregates clearly show the difference in interlayer water content of the two samples (Figure 7). Interlayer water is used in stacking of layers together by creating hydrogen bonding networks with anions within the layers. However, the LEuH-flocs has very little of these water content indicating their unilameller property (Figure 7).

The isolation of LEuH-flocs nanosheet is further verified by the difference in pore volume as compared to the LEuH-Cl aggregates (determined by Brunauer–Emmett–Teller (BET) and Barrett–Joyner–Halenda (BJH) measurements) (Figure 8), whereas the pores in LEuH-Cl aggregates have an average pore volume of 0.34 cc/g which is a characteristic of interparticular porosity and the LEuH-flocs nanosheets exhibit an average pore volume of 0.11 cc/g that is a characteristic of lack of porosity. In addition, after the BET experiments, the LEuH-flocs do not regain their original position as can be seen from the low pressure area in the isotherm where the two graphs (adsorption/desorption) should be a single line if the original structure is regained [21]. This clearly indicates the unstacked nature of the unilameller LEuH-flocs which lie on their c axis and a change in pressure leads to an increase in their randomness.

(a)

(b)

3.2. Application of the Unilameller LEuH-Flocs Nanosheets in Fluoride Adsorption Experiments

Ion exchange reaction of unilameller LEuH-flocs nanosheets in a fluoride aqueous solution is proposed to proceed via equation (2). The reaction mechanisms are schematically represented in Figure 9. The fluoride sorption reaction was monitored titrimetrically using chloride concentration in the supernatant solution after the ion exchange reactions. The reaction was found to complete in 2 minutes:

The sorption experiments of fluoride anions from aqueous media were carried out with the unilameller LEuH-flocs nanosheets and compared to LEuH-Cl aggregates for 6 minutes (Figure 10). Unilameller LEuH-flocs nanosheets had the highest fluoride loading capacity of 40 mmol/g as compared to ∼20.0 mmol/g exhibited by LEuH-Cl aggregates (Figure 10). Note that LDH-Cl (Mg/Al with a molar ratio of 0.67 : 0.33, respectively) materials exhibit adsorption capacities of 3.3 mmol/g [22]. Hence, the newly synthesized unilameller LEuH-flocs provide an effective and fast chemisorption recyclable nanosorbent material reported so far for fluoride separation from water.

The sorption mechanisms in unilameller LEuH-flocs nanosheets are purely attributed to chemisorption as its data fit perfectly with the Langmuir model (Figure 11) [23]. This is further supported with the type iii isotherm recorded with its BET isotherms (Figure 8). In contrast, LEuH-Cl aggregates sorption mechanisms could be attributed to both physisorption mechanism and chemisorption mechanisms due to its type ii BET isotherm and the low R² values of the Langmuir model [21]. Specifically, the adsorption in LEuH-Cl (hydrotalcite-like compounds) is initiated at the edges (physisorption mechanism) followed by ion exchange (chemisorption).

(a)

(b)

Anion adsorption behaviour of hydrotalcite-like compounds has been previously reported to occur at their edges through physisorption mechanisms [24–26]. However, delamination of LEuH-Cl aggregate materials into unilameller LEuH-flocs nanosheets provides a new pathway in which the exposed chloride ions are easily exchanged with fluoride ions from aqueous media. The reaction is fast and effective and has a higher fluoride loading rate than all other reported fluoride adsorbents [27].

The chemisorption process is further verified by the FHF⁻ covalent bond that shows FTIR vibrations at 578 cm⁻¹ (Figure 6) [28, 29]. The chemisorption process does not interfere with the surface morphology of the unilameller LEuH-flocs nanosheets as is depicted in the images taken after the adsorption experiments by both SEM and HRTEM (Figures 2 and 3). In addition, the XRD patterns of the fluoride-adsorbed unilameller LEuH-flocs nanosheets have similar peaks to the starting materials LEuH-flocs (Figure 4).

After calcination at 500°C to remove the adsorbed fluoride ions, the resultant LEuH-spinels were reused in fluoride adsorption for at least ten times giving similar adsorption capacities (Figure 12). It also noted that the spinels could also be dispersed in a NaCl solution (1 M) to reconstruct to the original LEuH-Cl starting material (Figure 13). It is however observed that when LEuH calcined spinels are used directly to adsorb fluoride ions, the resultant morphology is different from LEuH-flocs material (Figure 13(d)). However, this change in morphology does not affect adsorption capacity as can be seen from subsequent reuse experiments (Figure 12).

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(b)

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4. Conclusions

In summary, we have been able to isolate unilameller nanosheets from a colloidal solution of europium-containing layered rare-Earth hydroxide material (LEuH-Cl) by changing its pH from 6.5 to 11.5 in an aqueous medium. The resultant unilameller LEuH-flocs nanosheets exhibit fluoride chemisorption ability of 40 mmol·g⁻¹ as compared to LEuH-Cl aggregates of ≈20.0 mmol·g⁻¹ and LDH-Cl aggregates of 3.3 mmol·g⁻¹. And the chemisorption reaction is complete in two minutes with the resultant adsorbent being reusable after calcination at 500°C.

Data Availability

All the necessary information required for replication of this work and/or conducting secondary analysis are included within the article.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

This study was financially supported from National Research Fund of Kenya (2016/17). The RSC Allan Ure Bursary fund of 2017 and Jaramogi Oginga Odinga University of Science and Technology are acknowledged.

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Copyright © 2020 Solomon Omwoma et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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