Synthesis and investigation of SiO2-MgO coated MWCNTs and their potential application

In the present publication, multiwalled carbon nanotubes (MWCNT) coated with SiO2–MgO nanoparticles were successfully fabricated via sol–gel method to facilitate their incorporation into polymer matrices. Magnesium acetate tetrahydrate and tetraethyl orthosilicate were used as precursors. The coated MWCNTs were characterized by transmission electron microscopy (TEM), X–ray diffraction (XRD) and Raman spectroscopy methods. These investigation techniques verified the presence of the inorganic nanoparticles on the surface of MWCNTs. Surface coated MWCNTs were incorporated into polyamide (PA), polyethylene (PE) and polypropylene (PP) matrices via melt blending. Tensile test and differential scanning calorimetry (DSC) investigations were performed on SiO2–MgO/MWCNT polymer composites to study the reinforcement effect on the mechanical and thermal properties of the products. The obtained results indicate that depending on the type of polymer, the nanoparticles differently influenced the Young’s modulus of polymers. Generally, the results demonstrated that polymers treated with SiO2-MgO/MWCNT nanoparticles have higher modulus than neat polymers. DSC results showed that nanoparticles do not change the melting and crystallization behavior of PP significantly. According to the obtained results, coated MWCNTs are promising fillers to enhance mechanical properties of polymers.

The joint application of two geometrically different fillers, such as MWCNT coated with inorganic nanoparticles may reduce the total filler content due to the co-supporting effect of the two fillers. These crystalline and fiber shaped filler materials together may open a promising path in the polymer industry to produce polymer composites at low filler content and low costs.
The main goal of this work was to synthetize silica and magnesia coated MWCNTs to get maximum guarantee of perfect dispersion and investigate their effect on the properties of polymers. Attempts on synthesizing SiO 2 -MgO coated MWCNT/polymer composites were not yet extensively investigated, thus this work might present useful information for synthesis and investigation in the area of polymer science.

Experimental Details
chemicals. All 4 ] from Sigma-Aldrich, ethanol solvent from VWR, and ammonia solution from MolarChem were used without further purification for the preparation of the nanocomposite materials. The synthesis of MWCNTs was performed via catalytic chemical vapor deposition (CCVD) in a rotary oven at 720 °C applying Fe-Co/CaCO 3 catalyst, nitrogen atmosphere and acetylene as carbon source. Using this synthesis process and catalyst, MWCNTs were selectively formed without amorphous carbon or catalyst particles encapsulated inside. The quality of the pristine MWCNT is crucial for both the nanocomposite and the polymer fabrication, and therefore, the purification of MWCNTs is an essential step in the beginning of experiments. The support and catalyst particles were removed by washing the MWCNT product with diluted hydrochloric acid, and afterwards with deionized water (MilliQ, 18.2 MΩ cm), until neutral pH was achieved. The average diameter of MWCNTs is about 20-60 nm, and the average lengths range from afew hundred nanometers to a couple of micrometers (Fig. 1).
PA (11)  characterization methods. To verify and examine the formation of the SiO 2 -MgO layer on the surface of MWCNTs, TEM (FEI Tecnai G 2 20 X-TWIN) was used. For TEM investigations, a small amount of the sample was dispersed in ethanol via ultrasonication for 15 min then a small drop of the suspension was transferred onto a carbon film covered Cu TEM grid (Electron Microscopy Science, CF200-Cu). The crystal structure of the layer was investigated by XRD (Rigaku Miniflex II Diffractometer, angle range θ = 3-90) utilizing characteristic X-ray radiation (CuKα). The nanocomposites were also studied by Raman microscope with a built-in λ = 532 nm laser (Thermo Scientific DXR, spectrum acquisition time: 9 mins) in order to investigate whether the characteristic vibrations change of the species upon adding them to each other, which informs us about the presence of new interactions. The coated MWCNT/polymer composites were examined with scanning electron microscopy (SEM) with a cold field emission gun operating in the range of 5-15 kV (Hitachi S-4700 Type II FE-SEM). The crystallization and melting behavior of the coated MWCNT/polymer composites were investigated by differential scanning calorimetry (DSC). DSC measurements were carried out by a TA Instruments DMA Q800 device, where X c is the degree of crystallinity, wt% is the weight fraction of MWCNT, ΔH m is the heat of fusion (enthalpy of melting) of nanocomposite, and ΔH m 0 is the heat of fusion of 100% crystalline PP 47 The mechanical properties of the composites were characterized by tensile tests, using an Instron 3366 tester at room temperature with a crosshead speed of 200 mm/min. In all the cases, three samples with the dimensions of 80 × 10 × 1 mm were measured and the mean values with standard deviation (SD) were calculated. preparation of Sio 2 -Mgo coated MWcnt nanocomposites. As the first step of synthesizing of SiO 2 -MgO coated MWCNT nanocomposites, oxidation was applied to produce carboxyl groups on the surface of MWCNTs. Carboxyl functionalized MWCNTs (f-MWCNTs) were prepared by ultrasonically dispersing the MWCNTs in 60 mL 3:1 mixture of HNO 3 :H 2 SO 4 for 15 min. Afterwards, the mixture was stirred for 6 h at 65 °C, then MWCNTs were filtered in a membrane filtration apparatus (Durapore ® VVPP membrane filter, pore size 0.1 µm) and washed with deionized water until pH = 7 was achieved. Finally, the functionalized and filtered MWCNTs were dried overnight at 70 °C. The SiO 2 -MgO/MWCNT nanocomposites were prepared by sol-gel technique, by varying the MWCNT loading. The initially predetermined amount of f-MWCNTs -varying between 0% and 5% by weight to calculated (5 g) total final weight of nanocomposites -was added to 60 cm 3 ethanol and the suspension was sonicated for 30 min (solution A). Then, magnesia and silica precursors (molar ratio of Mg:Si = 3:4) were sonicated for 45 min in ethanol (Solution B). Afterwards, solution A was was vigorously stirred by a magnetic stirrer, and solution B was added in droplets (approximately 2 mL/min) to Solution A. To achieve the condensation reaction, the pH was set to 9-10 with 25% ammonia solution. The final mixture of Solution A and B was stirred overnight at room temperature to achieve the formation of a highly viscous gel. This gel was then placed in a drying furnace at 70 °C for 48 h to evaporate the solvent. After the drying process, white (samples without MWCNTs) and grayish-black (samples with MWCNTs) materials were obtained. Finally, the powder product was annealed in air at 400 °C for 4 h. The homogeneous white and grayish-black products were collected and pulverized into fine powder in an agate mortar.
preparation of Sio 2 -Mgo coated MWcnt polymer composites. Due to the polar hydroxyl, carbonyl and amid functional groups, the PA matrix is capable of adsorbing moisture from the atmosphere, and for this reason, the drying process is a key step during the synthesis. Skipping this procedure may cause a damage on the surface of the polymer and due to the breakage of polymer chains, caused by hydrolysis, we may experience significant deterioration in the mechanical properties. Therefore, PA was dried overnight at 60 °C in a drying furnace.
PA, PE and PP composites were prepared by the addition of SiO 2 -MgO/MWCNT nanocomposites. 50 g of polymer and 0.5 g talc-like oxide coated MWCNT nanocomposite was measured into an internal laboratory mixer (Brabender GNF 106/2). In case of PE and PP, the mixing temperatures were 230 °C and 250 °C for PA. After the heating of the laboratory mixer, half the volume of the polymer granules were added and stirred approximately for 5 min. Afterwards, the second half of the granules and SiO 2 -MgO/MWCNT nanocomposites were added to the polymer blend and the mixture was further stirred for 10 min under constant conditions. The applied rotor speed was kept between 40-50 rpm. A rapid increment of the measured torque was observed at the beginning of the mixing procedure. After a few minutes, the torque was stabilized (4.5 Nm) and remained constant. After the incorporation and mixing, the hot molten compounds were removed from the mixer chamber and the composites were compression moulded (Fontune SRA 100) into 115 × 115 × 1 mm sheet at 250 °C, applying 13 kN compression force. Finally, uniform samples were cut out of these sheets for tensile tests and DSC investigations.

Results and Discussions
investigations of Sio 2 -Mgo/MWcnt. The grayish-black color of samples after the annealing step indicated that the inorganic coating on the surface of MWCNTs was successfully formed. Nanocomposites were investigated with TEM to verify the presence and quality of SiO 2 -MgO coating. Before TEM investigation nanocomposites were pulverized into fine powder in an agate mortar and were sonicated using ultrasonic bath for an extended period of time (15 min). Despite these radical sample pre-treatment, nanoparticles were still detectable on the surface of MWCNTs. Figure 2 shows the micrographs of nanocomposites with different weight ratio of MWCNT. In the samples containing 1 wt% MWCNT mainly nanoparticles separated from the MWCNTs were observed (Fig. 2a). As it can be seen in Fig. 2b-f, with increasing MWCNT content the coverage of their surface seems more homogeneous. The investigation verified that coverage on the surface is quite similar to each other, no significant differences were observed in the quality of coating and evidently, every sample contains separated nanoparticles from the MWCNTs. Investigations revealed that the oxide nanoparticles are in the size range of 10-70 nm and the thickness of the coating is approximately 5-10 nm.
Afterwards, a reference sample of SiO 2 -MgO was investigated by SEM to gather more data about the shape and size of the particles. In Fig. 2g it can be clearly observed that the reference sample contains small particles, which form bigger spherical particles. Based on the SEM studies, the average diameter of these spherical particles is 75.60 nm ± 29.55. Figure 3 shows the diffraction patterns of each SiO 2 -MgO/MWCNT nanocomposites (label of the nanocomposites based on their MWCNT content). As it can be seen -and discussed further in details -the XRD www.nature.com/scientificreports www.nature.com/scientificreports/ measurements confirmed the results of TEM investigations. In the XRD diffraction of reference sample, four characteristics reflections can be observed: the wide reflection at 2θ = 25° suggests an amorphous characteristic of SiO 2 (marked with ❏), which reflection overlaps with those of MWCNTs (marked with ✷ at 2θ = 26.04°). We can also notice that by increasing the amount of MWCNTs, this reflection becomes more prominent. Reflections at 2θ = 42.75°, 62.16° and 78.63° belong to MgO, (200), (220), (222) (marked with ✶), respectively. Another broad reflection can be seen at 2θ = 11.63°, which could not be identified unequivocally, since phyllosilicates have different variations, which are rather similar to each other. Therefore, this reflection might belong to chrysotile, enstatite or talc.     www.nature.com/scientificreports www.nature.com/scientificreports/ XRD and Raman methods confirmed the presence of the inorganic layer on the surface of MWCNTs but they do not give any information about the chemical bonding between the inorganic layer and MWCNTs. In our research group, the nature of connection between MWCNTs and inorganic particles was investigated earlier by Fourier-transform infrared spectroscopy method as well and the formation of chemical bonding between MWCNTs and inorganic layer was proved. This results can be adopted with certainty in case of our samples 50 . investigations of coated MWcnt/polymer composites. After the tensile tests, we investigated the fracture surface of the polymer by SEM. The samples were sputtered with a gold -palladium coating to improve the conductivity of the samples. Creating a conductive metal layer on the composites inhibits charging, and improves secondary electron signal, which is required for topographic examination.   www.nature.com/scientificreports www.nature.com/scientificreports/ The bands of SiO 2 -MgO and MWCNTs cannot be identified unambiguously in the full range of the spectra (Fig. 8). However, the 2600-3200 cm −1 range of spectra ( Fig. 9) shows that the SiO 2 -MgO nanoparticles obviously have an effect on the intensity and appearance of the bands of PP. With increasing MWCNT content, the intensity of most characteristic PP peaks proportionally decreased. The changes in band shapes are also well visible, which corresponds to the different optical properties of the composite sample.
Physical properties of the coated MWCNT/polymer composite samples were examined by tensile tests and DSC. The effects of nanofillers on the mechanical properties are summarized in Table 1 and Fig. 10. By examining these data, we also observed that the mechanical properties of the MWCNT/polymer composite strongly depend on the shape of the nanofiller, the concentration of MWCNT, and the interaction between the filler material and the polymer matrix 51,52 .
As it can be seen in Fig. 10a, the Young's modulus of the MWCNT/PA nanocomposite was lower than that of the neat polymer This observation can be explained by the tendency of MWCNTs to form bundles because of the strong Van der Waals interaction between the MWCNTs. However, coated MWCNTs provided a significant increase in the mechanical properties of composites. SiO 2 -MgO nanoparticles on the surface of MWCNTs decreased the aggregation tendency of MWCNTs. The sample containing SiO 2 -MgO/5 wt% MWCNT has a much lower Young's modulus. This observation can be explained with the presence of the agglomerated nanoparticles. It is important to mention that with electron microscopy we can investigate only a small amount of nanocomposite. SiO 2 -MgO/MWCNT sample can contain uncovered MWCNT and also free inorganic nanoparticles which can agglomerate and hereby negatively influence the mechanical properties of the polymer matrix. In case of each PE composite samples, the Young's moduli were lower than the Young's modulus of the neat polymer (Fig. 10b). Previous publications already investigated widely the effects of particle size 53-55 , particle-matrix interaction on the mechanical properties of composites [56][57][58] . The unfavorable effects can be explained by the weak interaction between the filler material and the matrix. Due to the lack of suitable interaction between the filler material and the polymer, the particles tend to agglomerate, and their movement causes vacancies in the matrix. These vacancies may set up deformations in the PE matrix worsening the mechanical properties. By increasing the MWCNT content, this effect is reduced because of the combined effect of inorganic nanoparticles and the  www.nature.com/scientificreports www.nature.com/scientificreports/ fiber-like MWCNTs. Figure 11c illustrates the results of the tensile tests of PP composites. It can be observed that nanoparticles positively influenced the mechanical properties of the matrix. The Young's modulus of the neat PP was 850 MPa, which increased to 1555 MPa as an effect of SiO 2 -MgO/MWCNT nanoparticles. The wide error bar in the case of the samples containing SiO 2 -MgO/1 wt% MWCNT and SiO 2 -MgO/2 wt% MWCNT can be explained by the fact that only a small amount of filler material was incorporated into a large amount of polymer, and thus the homogenous dispersion in the matrix is more difficult to achieve. Based on the TEM images, it can www.nature.com/scientificreports www.nature.com/scientificreports/ be concluded that the separated SiO 2 -MgO nanoparticles in the samples can also impair the mechanical properties. In the SEM picture already seen (Fig. 5e) MWCNTs connect the broken parts of the polymer and the tensile tests showed strengthened properties, from which we can conclude that these SiO 2 -MgO/MWCNT nanoparticles -similar to the case of reinforced concrete -keep the polymer parts together.
The addition of SiO 2 -MgO/MWCNT nanofillers into the polymer matrices also influenced the strain at break values. Based on the results illustrated in Fig. 10a-c, it could be generally inferred that the strain at break values of the unfilled polymers were higher than that of the filled polymer composites. Whilst investigating the shape of the fillers, we can see that the application of a fiber-shaped reinforcement material resulted in a higher strain at break value, which verified the fact that different types of filler materials have dissimilar effects on the mechanical properties. As Fig. 10a represents, SiO 2 -MgO/MWCNT fillers make the polymer matrix more rigid, but by increasing the content of MWCNT, an even higher strain at break value can be achieved. It can be clarified that contrary to fiber reinforcement, SiO 2 -MgO fillers have irregular shape, and thus nanoparticles cannot properly transmit stress from the matrix 59 . In Fig. 10b,c, higher strain at break values can be observed, which can be explained by the lower dispersity of nanoparticles. Previously, patterns were investigated, in which nanoparticles did not accumulate and for this reason resulted higher value.Summarizing the results of tensile test, it can be concluded that SiO 2 -MgO/MWCNT nanocomposites changed the rigidity of polymers. This fact confirmed the good dispersity of the MWCNTs in the polymer matrices. Figure 11 shows the typical DSC curves of SiO 2 -MgO/MWCNT_PP nanocomposites. The endothermic peak at around 160 °C represents the melting temperature of PP. From Fig. 11 it can be obviously seen that the filler contentdid not influence significantly the melting temperature at melting point. The melting temperature, crystallization peak temperature, heat of fusion and degree of crystallinity of the nanocomposites are summarized in Table 2. As represented in Table 2, the melting and crystallization temperatures of the polymer nanocomposites did not change significantly as the MWCNT content increased. We can also see that the crystallinity percentage of SiO 2 -MgO/MWCNT_PP decreased slightly with increasing MWCNT content, but no significant changes could be observed. This observation can be explained by the nucleating activity of MWCNT networks, which can influence the mobility of polymer chains and slow down the crystal growth. This observation correlates with others, which demonstrated that a competition between nucleation and confinement appears. The curves of PA and PE composites represented identical results, thus they arenot reported in this study.

conclusions
This article presented the synthesis and investigation of SiO 2 -MgO coated MWCNT nanocomposites and their polymer composites. Coated MWCNT nanocomposites were prepared by sol-gel technique with different multiwalled carbon nanotube content. TEM, XRD and Raman investigations proved that the surface of MWCNTs was successfully coated with inorganic nanoparticles, and after annealing, the desired SiO 2 -MgO layer was formed. Based on the tensile test results, we conclude that in the case of PA and PP matrix, the nanomaterials positively influenced the moduli. We observed that the shape of the fillers can influence the strain at break values. In general fiber-shaped reinforcement material can cause higher strain at break values. In case of our samples aggregated   Table 2. Crystallization and melting properties of SiO 2 -MgO/MWCNT_PP polymers. Tc crystallization temperature, Tm melting temperature, ΔH heat of fusion, X percent crystallinity after first heating (a) and second heating (b).