PAN—Composite Electrospun-Fibers Decorated with Magnetite Nanoparticles

Abstract

The results of the synthesis of PAN(polyacrylonitrile)-magnetite composite fibers using the electrospinning method are presented. The electrospinning installation included a rotating drum collector for collecting fibers. Magnetite nanoparticles were synthesized using chemical condensation from an iron chloride solution. It was shown that homogeneous Fe₃O₄ magnetite nanoparticles with particle sizes of 6–16 nm could be synthesized using this method. Magnetite nanoparticles were investigated using X-ray diffraction analyses and transmission electron microscopy. Based on magnetite nanoparticles, composite PAN/magnetite fibers were obtained through electrospinning. The obtained composite fibers were investigated using scanning electron microscopy, X-ray diffraction analyses, and elemental analyses. It was shown that the magnetite nanoparticles were uniformly distributed on the surface of the fibers. A comparison of PAN fibers without any added magnetite to PAN/magnetite fibers showed that the addition of magnetite led to a decrease in the value of the fiber diameter at the same polymer concentration and under the same electrospinning process conditions.

1. Introduction

The magnetic properties of materials are used in science and technology, including acoustic systems, proximity sensors [1], electric machines [2], magnetic separators [3], cell phones, cameras, etc [4,5,6,7]. Magnetic nanomaterials play an important role in nanomedicine and have led to the development of new methods of magnetic diagnostics, such as magneto resistive and microhall (μHall) biosensors, magnetic particle spectroscopy, etc. Magnetic nanoparticles are also used as contrast agents in magnetic resonance tomography and as indicator materials in magnetic particle imaging [8].

Transitioning to the nanoscale has led to the formation of a new direction in the science of magnetic materials: magnetic nanomaterials. The composition, structure, and properties of magnetic nanomaterials vary widely and depend on the starting materials, synthesis methods, and practical tasks they are aimed at solving. Most commonly, magnetic nanomaterials are synthesized from Ni, Co, and Fe. Among magnetic nanomaterials, Fe-based compounds occupy a leading position, especially Fe₃O₄ magnetite.

According to the classification of nanomaterials based on their geometrical and structural characteristics, magnetic nanomaterials can have a 0D (zero-dimensional) structure, such as magnetic nanoparticles and nanopowders. The review [9] represents the methods used in the synthesis of magnetic nanoparticles, 90% of which are chemical methods. The issues related to nanoparticle modification by organic and inorganic compounds, polymers, and bioactive molecules are discussed. Further, methods of protein immobilization using magnetic nanoparticles, mainly based on Fe₃O₄, are discussed. There are methods of achieving the simultaneous synthesis of Fe₃O₄ and Co₃O₄ oxides mixtures within the flame [10]. Further, based on magnetite nanoparticles, the “core-shell” type structures are created. In paper [11], the synthesis of the Fe₃O₄/SiO₂ and CoFe₂O₄/SiO₂ structures through co-precipitation or the hydrothermal synthesis of Fe₃O₄ was shown. The obtained Fe₃O₄ was a coated surface with a layer of silicon dioxide, and functionalization was carried out with 3-aminopropyl-triethoxysilane. The reduction in the saturation magnetization of the magnetic cores was achieved through coating formation and functionalization [12]. Various magnetite-based core-shell structures are also presented in the review [13]. One of the most intensively developing areas is the production of magnetic fluids, and recently, magnetic nanofluids, including those based on magnetite nanoparticles [14].

One-dimensional (1D) structures include magnetic nanofibers, nanorods, nanotubes, and other one-dimensional configurations. In paper [15], a method of obtaining oriented porous fibers from magnetite (>96% yield) using hydrothermal methods in an aqueous solution of citric acid with a protein addition was proposed. The obtained magnetite fibers have a cylindrical shape with a diameter of 120 nm and are characterized by their porous structure, with a pore size of <5 nm and a high specific surface area (123 m²/g). The influence of synthesis conditions on the structure of the obtained fibers was studied. The possibility of the application of magnetic fibers as an effective adsorbent for the removal of some toxic chemical substances on the example of Cr(VI) (anions), Hg(II) (cations), and polychlorinated biphenyl (non-polar molecules) was shown.

In addition to obtaining fibers from pure magnetite, many studies have been devoted to obtaining magnetite-based nanofibers [16,17]. In paper [18], the results of the synthesis of PAN/Fe₃O₄ magnetic nanofibers using the electrospinning method are presented. The authors synthesized Fe₃O₄ nanoparticles with an average diameter of about 8 nm. Three concentrations of polyacrylonitrile (PAN, from 8 to 14 wt. %) were used to study the effect of PAN concentration on the diameter and morphology of PAN/Fe₃O₄ nanofibers. Spherical nanoparticles were formed on the fiber’s surface, and the number of spheres gradually decreased with the increasing PAN fraction. When the PAN content exceeded 14 wt. %, no formation of spherical particles was observed in the products. The effect of the addition of LiCl to the PAN solution on the structure of the obtained fibers was also considered.

In [19] the authors synthesized PAN/magnetite fibres by electrospinning method. PAN solution with 14% concentration was prepared in dimethyl sulphoxide at a mass ratio of PAN to magnetite of 1.0:1.8 respectively, and the diameter of magnetite nanoparticles was 50–100 nm in the range. As a result, fibers with an average diameter of 100 ± 45 nm were obtained. Many globular structures were observed within their structure. The authors studied the magnetic properties of PAN/magnetite fibers after electrospinning, stabilization, and carbonization at temperatures of 500 and 800 °C. It was shown that their magnetic properties (hysteresis loop, coercive field) change, which may be explained by a change in the distance between individual particles after stabilization and carbonization and, as consequence, the strengthening of the influence of the particles on one another. Various additives in the composition of the PAN fibers affect the structure at the stage of formation, as well as the processes of further processing. In [20], the effect of 1–10 wt. % of Fe/FeO nanoparticle additives on the structure of PAN fibers after electrospinning and during the stabilization and carbonization processes was investigated. The authors paid much attention to the study of the carbonization process. The influence of the temperature, heating rate, holding time, and cooling rate during carbonization on the structure of the final PAN and Fe/FeO carbon fibers is shown.

An important task is to obtain oriented or ordered magnetic fibers. Thus, in paper [21], the preparation of partially oriented PAN/magnetite magnetic nanofibers on the partially conductive substrates of polypropylene and copper tape is reported. In addition to classical electrospinning, a new direction—bubble electrospinning—is being developed; some features and examples of its implementation are presented in papers [22,23].

Two-dimensional (2D) structures—nanofilms, nanocoatings, nanosheets, etc.—are being actively studied. Hybrid films based on sisal cellulose and magnetite nanoparticles were obtained in [16]. Magnetite nanoparticles of a spherical shape, with an average diameter of 5.1 ± 0.5 nm, were coated with oleic acid and oleylamine to prevent agglomeration. The strength characteristics, elastic modulus, and magnetization of the films were also determined. The influence of magnetite nanoparticles on the formation of polystyrene-block-poly (N-isopropylacrylamide)/magnetite magnetic films was discussed in detail in paper [24]. Films were obtained using the spray coating method. It was shown that, during the initial stage of spray coating, the film containing 2 wt. % of magnetite demonstrated a faster process of complete coating formation compared to the reference. The films exhibit superparamagnetic properties, which make them suitable for magnetic sensors or information storage.

Three-dimensional (3D) structures include a new achievement in the area of aerogels—magnetic oxide-ceramic aerogel [25]. It is characterized by an ultralow density of 55 mg/mL and contains up to 98.7% air. A detailed description of the aerogel formation mechanism is provided, and the superparamagnetic and other properties of the material are considered. Paper [26] details obtaining magenta aerogels based on magnetite nanoparticles through freeze-drying Janus emulsion gels based on olive and silicone oils containing gelatin and sodium carboxymethylcellulose. The obtained aerogels are relevant for smart supercapacitors, biosensors, sorption, and the separation of oil spills. The morphology of the final structure was investigated depending on the initial compositions. In paper [27], the results of Mössbauer’s studies of magnetic polymer nanocomposites based on magnetite and polyvinyl alcohol were presented. For this purpose, a polymeric nanocomposite, based on Fe₃O₄ and polyvinyl alcohol (PVA), was synthesized using chemical coprecipitation from FeCl₃·6H₂O and FeCl₂·4H₂O (2:1). The amount of pure iron in the mixture was varied from 30 to 60 wt. %. It was shown that the nanocomposite based on magnetite and PVA represents separate phases: a magnetic component close to the stoichiometric composition of magnetite, a superparamagnetic nonstoichiometric component, and an intermediate weakly magnetic superposition component.

Magnetite and composites based on it have found their application or are promising for several practical applications. In particular, the shielding properties of concrete with the addition of magnetite nanoparticles were studied in paper [28] and showed better protection against microwave radiation in the frequency range from 0.7 to 13 GHz. The maximum electromagnetic interference suppression efficiency was 19.9 dB at 1.5 GHz, with a thickness of 10 mm and a magnetite content of 0.5 wt. % in the concrete.

The aim of this work was to synthesize composite fibers with magnetic properties. To achieve this, the tasks of synthesizing magnetite nanoparticles and obtaining composite fibers based on PAN with additives of magnetite nanoparticles were set. The novelty and practical significance of the work lie in the development of a method of chemical condensation for the synthesis of nanoparticles with a small dispersion in diameter and obtaining nanofibers from PAN with a uniform distribution of magnetite nanoparticles on the fiber surface through electrospinning.

2. Experimental Part

2.1. Synthesis of Fe₃O₄ Magnetite Nanoparticles

Magnetite Fe₃O₄ nanoparticles were synthesized through chemical condensation according to earlier work [29]. For this purpose, the following were prepared: an aqueous solution of iron (III) chloride hexahydrate (FeCl₃·6H₂O) at a concentration of 0.32 mol/L and iron sulfate heptahydrate (FeSO₄·7H₂O) at a concentration of 0.2 mol/L. Aqueous solutions of iron salts, each 325 mL in volume, were poured into a heat-resistant flask, stirred with a heated magnetic stirrer (ISOLAB), and 200 mL of a 25% aqueous ammonia solution (NH₄OH·H₂O) were gradually added at a rate of 1 drop/s. The temperature of the aqueous iron salt solution was maintained at 50 °C. The chemical reaction of the formation of magnetite nanoparticles was as follows:

FeSO₄·7H₂O + 2FeCl₃·6H₂O + 8NH₃·H₂O → Fe₃O₄↓ + 6NH₄Cl + (NH₄)₂SO₄ + 23H₂O

Magnetite nanoparticles were extracted from the solution with a permanent magnet, washed several times with water to neutralize the reaction, and then dried under normal conditions.

2.2. Preparation of PAN/Fe₃O₄ Solution and Obtaining of Composite Fibers

Polyacrylonitrile (with a molecular weight of 150,000 g/mol, DFL Minmet Refractories Corp., Shijiangzhuang City, China) was used as the main fiber-forming polymer. For this purpose, PAN and dimethylformamide (DMF, (CH₃)₂NC(O)H, 99.9%, Sigma-Aldrich, Darmstadt, Germany) were mixed at a ratio of 7:93 (wt.) with further homogenization for 2 h on a magnetic stirrer at a stirring speed of 100 rpm and a temperature of 70 °C. After the solution was completely homogenized, the prepared PAN solution was mixed with small portions of magnetite at a ratio of 20:1 (wt.). The suspension was placed in an ultrasonic bath (Grad Technology, Moscow, Russia) for 1 h at 30 °C to achieve uniform distribution of the magnetite nanoparticles in the polymer solution. To obtain composite PAN/Fe₃O₄ fibers, the electrospinning method was used. The schematic diagram of the unit is shown in Figure 1 [30].

The obtained PAN/Fe₃O₄ solution was filled into a 5 mL syringe. The electrospinning process was performed at an ambient temperature of 20–30 °C and a humidity level of 30–50%; the voltage was 12–15 kV, the feed rate was 1.0 mL/h, the feed current was 20 mA, the collector radius was 23 cm, the distance between the needle and collector was 12–15 cm, and the collector surface was covered with aluminum foil for nanofiber deposition (Figure 1).

2.3. Analytical Methods of Investigation for Fe₃O₄ Magnetite Nanoparticles and Composite Fibers

The Fe₃O₄ nanoparticles were examined on the MiniFlex300/600 diffractometer (Rigaku Corp., Tokyo, Japan) and the JEM-1011 transmission electron microscope (TEM) (JEOL, Tokyo, Japan). Scanning electron microscopy (SEM) was completed using the “Quanta 200i 3D” (FEI Company, Peabody, MA, USA) device with a built-in system of energy-dispersive spectroscopy (EDS) and a cryogenic vibrating sample magnetometer. The composite fibers PAN/Fe₃O₄ were investigated through X-ray diffraction analysis (XRD) (using the diffractometer DRON-4M (NPO “Burevestnik”, St. Petersburg, Russia) and SEM. For the study of the samples through XRD, the following shooting settings were used: an X-ray tube voltage of 30 kV, tube current of 30 mA, and the step motion of the goniometer at 0.05° 2θ, while measuring the intensity of the point up to 1.0. The rotational speed of the sample in its own plane was 60 rev/min. The processing of radiographs to determine the angular position and intensity of the reflection was carried out using the «Fpeak» program. The phase analysis used the «PCPDFWIN» program from the PDF-2 diffractometric database. The obtained spectra were identified using the JCPDS X-ray database.

3. Results and Discussion

Magnetite nanoparticles were surveyed using XRD, SEM, TEM, and EDS methods and a magnetometer. Figure 2 shows the SEM image, TEM image, and particle size distribution based on the TEM of the magnetite synthesized through chemical deposition. The obtained magnetite nanoparticles were characterized by a small variation in diameter. The predominant fraction of particles had sizes ranging from 6 to 16 nm, with the average size of the particles being 12.22 nm.

Particles of 50 nm and larger are also provided in the image, but the authors believe that these dimensions are due to the overlapping of the particles. The agglomeration of magnetic particles is due to the presence of high surface energy between the prepared magnetic nanoparticles and the presence of magnetic dipole–dipole interactions [31]. A more detailed description of nanoparticle agglomeration processes can be found in [32]. To determine the chemical composition of the samples of obtained magnetite nanoparticles, elemental analysis was carried out using an energy-dispersive spectrometer. The energy-dispersive spectrum and the results of the study of the chemical composition are shown in Figure 3a. According to the results of the EDAX analysis, the mass fraction of iron (Fe) was 74.31% and the atomic fraction was 45.32%; the mass fraction of oxygen (O) was 25.69% and the atomic share was 54.68%. The X-ray pattern of magnetite nanoparticles, shown in Figure 3b, contains 9 diffraction peaks at the angles of 2θ = 18.5; 30.1; 35.5; 43.2; 53.6; 57.1; 62.7; 71.3, and 74.2 degrees, which correspond to the crystal planes of the magnetite phase (111), (220), (311), (400), (422), (511), (440), (620), and (533), respectively [33]. According to the Scherrer equation, the average particle size, t = λ/(βcos θ), can be estimated from the CuK_α(λ) X-ray wavelength, Bragg angle (θ), and the total peak width at half-height (β) in the radians. The size of synthesized magnetite particles, using the Scherrer equation, was 10.4 nm, which did not contradict the TEM image data.

The values of the magnetic moment of the obtained samples of magnetite nanoparticles were measured on a cryogenic magnetometer. The measurement results are shown in Figure 4. The studies performed showed that magnetite nanoparticles pass into the superparamagnetic state, as indicated by the absence of hysteresis in the field magnetization curve. The transition to the supermagnetic state is explained by the transition of magnetite nanoparticles to a single-domain state, and by the fact that uniform magnetization is achieved throughout the volume.

To investigate the structure and morphology, the obtained PAN/Fe₃O₄ fibers were examined using scanning electron microscopy and EDS analysis. For comparison, PAN fibers obtained at the same polymer concentrations and under the same conditions for the electrospinning process, but without magnetite, were also studied. Figure 5 shows the SEM image of the pure PAN fibers without magnetite, and Figure 6 shows PAN/Fe₃O₄ fibers.

PAN fibers synthesized without the addition of magnetite nanoparticles have a smooth surface without surface defects, open porosity, and clusters. The addition of magnetite to the solution resulted in a reduction in the diameter of the fibres formed as a result of electrospinning. In comparison for PAN fibres the diameter is 0.924 μm and for PAN/Fe₃O₄ fibres the diameter is 0.345 μm. A similar decrease in fiber diameter with the addition of magnetite was observed by the authors of [34], who obtained nanofibers based on polyvinyl alcohol and magnetite by electrospinning. Further, in [35], the authors investigated the inclusion of magnetite nanoparticles during the electrospinning of PAN fibers. The addition of 10, 25, and 40 wt. % of magnetite resulted in a decrease in diameter: 165, 139, and 74 nm, respectively. The authors explain this process through the effect of magnetite nanoparticles on the properties of the polymer solution and the change in conductivity, viscosity, and surface tension. The authors in [34] experimentally found that increasing the magnetite content in the initial solution from 0.075 to 0.175 g led to a decrease in the fiber diameter from 186.5 to 131.4 nm and increases in saturation magnetization and residual magnetization. The obtained SEM images (see Figure 6) show a uniform distribution of magnetite nanoparticles over the entire fiber surface. Figure 7 shows the results of the elemental analysis of the composite fibers. High carbon content (65.95 wt. %) and a small amount of iron (9.33 wt. %) are observed, and nitrogen (17.49 wt. %) and oxygen (7.23 wt. %) are also present.

To detect a possible interaction between PAN polymer and magnetite nanoparticles during solution preparation and/or during the electrospinning of the fibers, PAN/Fe₃O₄-fibers were investigated using X-ray phase analysis.

According to the XRD results (Figure 8), it was found that the magnetite particles in the PAN-based fibers did not undergo any chemical transformation, retained their original chemical formula (Fe₃O₄) and crystal structure, and represented single-phase magnetite in the medium of the polymer matrix. It should be noted that there were peaks corresponding to the crystallites of silicon on the X-ray pattern since the sample was attached to a substrate of monocrystalline silicon during the analysis.

Studies were performed on the synthesis of composite fibers from polyacrylonitrile with the addition of the magnetite nanoparticles obtained through chemical condensation. The method of electrospinning from the PAN solution in dimethylformamide with the addition of magnetite nanoparticles was applied to form the nanofibers. Depending on the field of practical application, composite fibers must have given characteristics of magnetite nanoparticle diameters and fibers, magnetite particle distribution on the surface and/or fiber structure, porosity, etc. The resulting fibers have the prospect of potential practical applications, such as for photovoltaics and photon sensing; the absorption of microwave and other radiation as a shield [36]; as a catalyst [37]; in wastewater treatment for heavy metal ions and organic pollutants; for drug delivery in biotechnology and biomedicine, in cell growth and tissue engineering; the creation of magnetic sensors [38,39]; as electrode material for lithium metal anodes [40], in medicine as a method of cancer treatment through magnetic hyperthermia [41], and as a biomedical adsorbent [42,43].

4. Conclusions

This study describes the results of experiments on the synthesis of magnetite nanoparticles through chemical condensation. Their average size was 10–12 nm, which was confirmed by the results of XRD, TEM, and SEM analyses. The magnetic properties of magnetite nanoparticles were studied. The studies performed showed that magnetite nanoparticles passed into the super-paramagnetic state, as indicated by the absence of hysteresis in the field magnetization curve. The transition to the supermagnetic state was explained by the transition of magnetite nanoparticles to a single-domain state, and by the fact that uniform magnetization was achieved throughout the volume. Magnetite nanoparticles were used to create composite PAN/Fe₃O₄ fibers by adding magnetite to the PAN solution to obtain a homogeneous suspension. Fibers were produced from a 7 wt. % PAN/Fe₃O₄ suspension in dimethylformamide through the electrospinning method. The SEM method showed that the magnetite nanoparticles were uniformly distributed throughout the fiber structure, with an average diameter of 0.345 μm. A comparison of PAN fibers without magnetite and PAN/Fe₃O₄ fibers showed that the addition of magnetite led to decreases in the diameters of the fibers at the same polymer concentrations and conditions of the electrospinning process. The resulting PAN/Fe₃O₄ composite fibres can be used in several practical applications, including sensors, magnetic materials, electronics, etc.