Abstract
A new electrospinning process was developed for preparing TiO2 nanofibers using a water-soluble Ti-precursor, [bis(kappa1O-hydroxo)(bis(kappa2O,O′-lactato)titanium(IV)] commonly known as titanium(IV) bis (ammonium lactato) dihydroxide (TiBALDH). The importance of the study is justified by the fact that Ti-precursors used for electrospinning, sol–gel, hydrothermal and other fiber synthesis processes are mostly non-water soluble. Accordingly, anatase TiO2 nanofibers of diameter between 20 and 140 nm were synthesized by electrospinning and annealing. Polyvinylpyrrolidone (PVP) and different concentrations of TiBALDH were dissolved in a mixture of water, ethyl alcohol and acetic acid to optimize the electrospinning conditions. The thermal decomposition and fragmentation of PVP, TiBALDH and the fibers with 50% mass fraction of TiBALDH were studied by TGA-MS measurements. The fibers were then annealed at 1 °C min−1 until 600 °C. The TiO2 fibers were characterized using SEM–EDX, FTIR and XRD
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Introduction
Titanium dioxide is used in a number of applications including self-cleaning, antimicrobial thin film coatings, photocatalysis, gas sensing and dye-sensitized solar cells [1,2,3,4,5]. This has led to a lot of research in the preparation of TiO2 nanofibers with well-controlled morphology [6,7,8,9,10]. Many methods of synthesis of TiO2 nanofibers have been developed including sol–gel, hydrothermal and electrospinning [11,12,13]. Electrospinning as a method of synthesis of nanofibers has been widely reported [14,15,16,17]. The technique is a versatile and efficient method for synthesizing uniform fibers with large specific surface area [18,19,20,21]. In electrospinning, high static voltage is applied to a polymer solution or melt, which can contain a precursor salt of metal oxide in a syringe. The solution or melt is ejected from the needle tip, accelerated by electric field and is collected on a grounded substrate in form of thin continuous fibers [17, 22,23,24]. The nanofiber properties can be controlled to offer more flexibility in surface functionalities of the end product. Many studies use Ti-alkoxides and Ti-halides as precursors for the synthesis of TiO2; however, these are insoluble in water [25]. There is a need to prepare TiO2 nanofibers from water-soluble precursors. This would enable coupling TiO2 with other metal oxides having water-soluble precursors. In this study, [bis(kappa1O-hydroxo)(bis(kappa2O,O′-lactato)titanium(IV)] commonly known as titanium(IV) bis (ammonium lactato) dihydroxide (TiBALDH) was used as the precursor in preparing TiO2 nanofibers. The structure of TiBALDH is shown in Fig. 1.
TiBALDH is a water-soluble titanium precursor with low reactivity [26, 27]. It has been used to make various titania nanomaterials. Mockel et al. reported that TiBALDH was utilized to produce almost monodispersed anatase nanocrystals by thermohydrolysis [28]. Mayya et al. [29] reported a nanoscale coating of gold nanoparticles with titania based on TiBALDH. Lee et al. [30] prepared anatase TiO2 nanoparticles coupled with carbon nanotubes (CNTs) by controlled hydrolysis of TiBALDH in CNTs containing aqueous media. Hongzhi et al. [31] prepared TiO2 nanocrystals by hydrolysis and hydrothermal treatment of TiBALDH. There is only one report in which a water-soluble TiO2 precursor was used to synthesize TiO2 nanofibers by electrospinning. Nakane et al. [32] prepared hybrid nanofibers of poly(vinyl-alcohol) and titanium lactate by electrospinning. In their study, Nakale et al did not optimize the concentration for the precursors and only one set of concentration was published. However, no studies have been reported about the use of TiBALDH as a precursor in the synthesis of TiO2 nanofibers by electrospinning. There are also no reports on thermal analysis of TiBALDH which is important since to obtain crystalline TiO2, an annealing step is often needed.
In this study, TiO2 nanofibers were prepared by electrospinning a mixture of alcoholic and aqueous solutions of polyvinylpyrrolidone (PVP) and TiBALDH. We studied how the properties of the electrospun fibers could be controlled by using different concentrations of the precursor. The thermal decomposition and fragmentation of PVP, TiBALDH and the fiber with 50% mass fraction of TiBALDH were studied by TGA-MS measurements. The thermal properties of the electrospun fibers were investigated in nitrogen by simultaneous thermogravimetry/differential thermal analysis (TG/DTA). The electrospun fibers were annealed at 600 °C to remove the polymer component, decompose the precursor and obtain TiO2 nanofibers. The electrospun and annealed nanofibers were characterized by scanning electron microscopy (SEM) and energy-dispersive X-ray spectroscopy (EDX). The fibers, PVP and TiBALDH were studied by Fourier transform infrared spectroscopy (FTIR). The annealed fibers were investigated by X-ray diffraction (XRD).
Experimental
Materials
All materials were analytical grade and used as received. Polyvinylpyrrolidone [PVP, (C6H9NO)n, K-90] and titanium(IV) bis(ammonium lactato)dihydroxide [(C6H18N2O8Ti) TiBALDH, 50 mass% in water)] were obtained from Sigma-Aldrich.
Preparation and characterization of TiO2 fibers
The polymer solution contained 20 mass% PVP dissolved in 1:1 mixture of acetic acid and ethyl alcohol. 2 mL of the polymer solution was mixed with 2 mL of an aqueous solution containing 50, 30, 25 and 10 mass% TiBALDH, respectively. The mixture was stirred for 6 h at room temperature. The mixed solution was loaded into a plastic syringe equipped with a needle for electrospinning. The feeding rate was 1 mL h−1, while the applied voltage was 25 kV. The fibers were collected on an Al foil screen covered by a polyethylene sheet.
For the thermal measurements, a 50 mass% solution of TiBALDH was carefullyFootnote 1 dried. TG/DTA–MS measurements for TiBALDH, PVP and as-spun fiber of 50 mass% TiBALDH were carried out using the TA Instruments’ Q600 simultaneous TG/DSC setup coupled to a Hiden Analytical HPR-20/QIC mass spectrometer. The measurements were carried out in flowing argon (flow rate = 50 cm3 min−1) in an alumina crucible and empty crucible as a reference. The sample mass was ca. 7 mg. Selected ions between m/z = 1–125 were monitored in multiple ion detection mode (MID) at a heating rate of 10 °C min−1.
The electrospun fibers were annealed in air to remove the polymer and decompose the precursor. The annealing was done at a rate of 1 °C min–1 up to 600 °C. The thermal decomposition of the electrospun fibers in nitrogen was investigated in an STD 2960 simultaneous DTA/TGA (TA Instruments Inc.) thermal analyzer. The samples were heated up to 600 °C using a heating rate of 10 °C min–1 in nitrogen.
The morphology of the as-spun fibers was studied by scanning electron microscopy (SEM) in a JEOL JSM-5500LV scanning electron microscope in a high vacuum mode at 20 kV. For the annealed samples, the SEM images were observed by a LEO 1440 XB electron microscope in a high vacuum mode with secondary electron detector. The EDX analysis of the annealed fibers was done using JEOL JSM-5500LV electron microscope. Before the measurement, the nanofibers were coated with a thin Au/Pd layer in a sputter coater. Fourier transform infrared spectroscopy (FTIR) measurements of carefully dried 50 mass% TiBALDH, PVP, electrospun and annealed nanofibers were recorded with a Nicolet 6700 apparatus in the 400–4000 cm−1 domain in transmittance mode. The sensitivity of measurements was 4 cm−1, and 64 scans were accumulated per spectrum. The XRD patterns were recorded by a PANalytical X’pert Pro MPD X-ray diffractometer using Cu Kα irradiation.
Results and discussion
TG/DTA–MS measurements were carried out to study how the TiO2 precursor, TiBALDH, affects the decomposition of PVP and the formation of TiO2. Figure 2 shows that the decomposition of TiBALDH is continuous showing two DTG maxima to 550 °C, while the decomposition of PVP takes place in practically one step between 340 and 468 °C without residue [33, 34]. The decomposition of the fiber with 50 mass% TiBALDH and 20% PVP is also continuous with three DTG maxima up to 550 °C. The decomposition of the fiber and both of its components is practically finished around 550 °C. In the temperature range up to about 100 °C, the evaporation of the solvents is expected.
The DTG–MS data are shown in Fig. 3a–f. In the samples of PVP (Fig. 3a) and the fiber of PVP/50 mass% TiBALDH (Fig. 3e), at first, water evaporation was detected. In addition, in TiBALDH, the appearance of fragments with 14–18 and 29–46 m/z ratio indicates a partial decomposition of the TiO2 precursor even below 100 °C (Fig. 3c, d). This is not surprising taking into account the hazard statements of TiBALDH. Above 100 °C, in the DTG curve of the composite fiber, the peaks characteristic for both of PVP and of TiBALDH was observed. However, the DTG maxima appeared at lower temperatures than in the pure components.
The most intense MS signals of PVP are those with m/z = 18 and 17. The intensity ratio of the peaks below 100 °C agrees with that of water. At higher temperatures, the intensity ratio changes as a result of the evolution of fragments NH3+ and NH4+. The intensity of the signals of the fragments with m/z = 14, 15 and 16 is about ten times less than of fragments m/z = 18 and 17. Besides these, low-intensity signals with a higher m/z ratio were also detected (Fig. 3b). The courses of the m/z signals follow well the course of the DTG signal. Since the decomposition was recorded in flowing argon using TG/DTA-MS, relative intense signals of H+ and H2+ (m/z = 1, 2) and C3+ (m/z = 36) were detected due to the reduction of the polymer (Fig. 4a). The molecular fragment of the PVP monomer with m/z = 111 was not found. The fragment with the highest m/z was detected at 112 (Fig. 4b) which most probably originates from the recombination of the fragment with m/z = 56 (see Fig. 4b). Besides, a low-intensity signal in PVP was detected at m/z = 68. The appearance of these signals is most probably a result of the fragmentation of the pyrrolidone ring (e.g., C2H2NO and C3H2NO).
During the decomposition of TiBALDH, only signals up to m/z = 46 ratio were detected (Fig. 3c, d). Fragments with m/z = 18, 29 and 31 had the most intense signals. These could be attributed to H2O+, C2H5+ and C2H2OH+ formed during the decomposition of TiBALDH (C6H18N2O8Ti).
The difference in the fragmentation of the as-spun fiber compared to the fragmentation of the components used for its preparation is that in the mixture all the detected signals were below m/z = 32 (Fig. 3f). This means that in the preparation of the TiO2 fibers TiBALDH catalyzes the decomposition of PVP.
Due to the very small differences in the molar masses of the expected CO2+, N2O+, NO+x fragments, their identification by this way was not possible. Based on the TGA measurements, the as-spun fibers should be annealed to 600 °C to obtain TiO2 fibers.
Figure 5 shows the comparison of various composite fibers in nitrogen and that the decomposition is continuous. The endothermic peaks in the DTA peaks are not sharp, because the precursor and the polymer components of the fibers decomposed without combustion. The decomposition occurred in three stages as discussed earlier. The mass of the residues was consistent with the increasing concentration of the precursor. The percentage yield for the TiO2 fibers varied depending on the concentration of the precursor, 50 mass% TiBALDH was 13.1%, 30 mass% TiBALDH was 10.7%, 25 mass% TiBALDH was 10.4% and 10 mass% TiBALDH was 9.4%.
The as-spun PVP/TiBALDH fibers had diameters between 310 and 800 nm depending on the concentration of TiBALDH. The fibers were annealed in air at a heating rate of 1 °C min−1 up to 600 °C. The slow heating rate was used to avoid disintegration of the oxide fibers [22]. The diameter of the as-spun and annealed fibers was larger when the concentration of TiBALDH was higher. After annealing, diameter of the fibers decreased significantly after annealing to 20–170 nm, as shown in Table 1.
From the SEM image of annealed fibers shown in Fig. 6, the fibers formed from 50 mass% and 30 mass% TiBALDH were smooth, while the fibers from 25 mass% and 10 mass% TiBALDH had some beads.
Results of EDX analysis are shown in Fig. 7. They confirmed the presence of titanium and oxygen in the annealed fibers. Ti peak was observed at 4.5 kV [35, 36]. The elemental composition in the annealed fibers is as shown in Table 1.
The results for the FTIR measurements of pure TiBALDH, PVP, as-spun and annealed composite fibers are shown in Fig. 8. The broadband around 3600 cm−1 can be assigned to O–H stretching vibration while the peak around and 3200 cm−1 can be due to N–H stretching vibrations in TiBALDH. The C–H asymmetric vibrations of the methyl group in TiBALDH and PVP were observed around 2980 cm−1. The sharp absorption bands around 1639 cm−1 can be assigned to C=O in the amide group in PVP. The peak around 1440 cm−1 can be assigned to O–H bending vibrations. The C–N stretching vibration absorption peaks in PVP were observed around 1290 cm−1 [33, 37, 38]. These absorption bands were also observed in the as-spun fibers. For the annealed samples, the absorption band around 630 cm−1 can be assigned to the Ti–O–Ti bonds [37]. The FTIR measurements of the annealed fibers confirmed that the polymer and the precursor were decomposed during annealing.
Figure 9 shows the XRD pattern of the annealed fibers. The fibers were crystalline with tetragonal structures. The XRD patterns exhibited strong diffraction peaks at 25° and 48° indicating TiO2 in anatase phase [35, 39]. The annealed fibers were indexed to ICDD 04-016-2837.
Conclusions
Anatase TiO2 nanofibers of diameter between 20–170 nm were synthesized by electrospinning using a water-soluble Ti-precursor. Polyvinylpyrrolidone and different concentrations of TiBALDH were dissolved in a mixture of water, ethyl alcohol and acetic acid followed by electrospinning at 20 kV to obtain nanofibers. The as-spun fibers were studied by TG/DTA-MS to establish annealing temperatures. The data of TGA-MS measurements revealed that TiBALDH catalyzes the decomposition of the as-spun fibers. During its decomposition, only fragments with m/z < 32 evolved. The fibers were annealed at 1 °C min−1 until 600 °C to form anatase TiO2 nanofibers. 50 mass% and 30 mass% TiBALDH concentrations formed smooth fibers.
Notes
According to the Safety Information the hazard statement of TiBALDH is H226-H319.
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Acknowledgements
Open access funding provided by Budapest University of Technology and Economics (BME). I. M. Szilágyi thanks for a János Bolyai Research Fellowship of the Hungarian Academy of Sciences and an ÚNKP-18-4-BME-238 New National Excellence Program of the Ministry of Human Capacities, Hungary. A GINOP-2.2.1-15-2017-00084, an NRDI K 124212 and an NRDI TNN_16 123631 grants are acknowledged. The research within project No. VEKOP-2.3.2-16-2017-00013 was supported by the European Union and the State of Hungary, co-financed by the European Regional Development Fund. The research reported in this paper was supported by the Higher Education Excellence Program of the Ministry of Human Capacities in the frame of Nanotechnology and Materials Science research area of Budapest University of Technology (BME FIKP-NAT) and Stipendium Hungaricum scholarship grant. Katalin Mészáros Szécsényi thanks the Ministry of Education, Science and Technological Development, Serbia (Project Number: ON172014)
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Otieno, O.V., Csáki, E., Kéri, O. et al. Synthesis of TiO2 nanofibers by electrospinning using water-soluble Ti-precursor. J Therm Anal Calorim 139, 57–66 (2020). https://doi.org/10.1007/s10973-019-08398-z
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DOI: https://doi.org/10.1007/s10973-019-08398-z