The Development and Characterization of Polycaprolactone and Titanium Dioxide Hybrids
Vol.07No.01(2018), Article ID:82580,17 pages
10.4236/anp.2018.71002
Mariana Sato de S. B. Monteiro1*, Maria Inês Bruno Tavares2
1Faculdade de Farmácia, Universidade Federal do Rio de Janeiro, Rio de Janeiro, Brazil
2Instituto de Macromoléculas Professora Eloísa Mano, Universidade Federal do Rio de Janeiro, Rio de Janeiro, Brazil
Copyright © 2018 by authors and Scientific Research Publishing Inc.
This work is licensed under the Creative Commons Attribution International License (CC BY 4.0).
http://creativecommons.org/licenses/by/4.0/
Received: January 4, 2018; Accepted: February 20, 2018; Published: February 23, 2018
ABSTRACT
Organic/Inorganic hybrid materials have been attracting much attention since they combine the advantages of inorganic materials with the properties of organic polymers. Titanium dioxide nanoparticles (TiO2) present good thermal stability, accessibility and catalytic properties. Polycaprolactone (PCL) is a biocompatible and bioresorbable material, which is being examined as biodegradable packaging materials, controlled drug release carriers and other medical applications. Hybrids based on PCL containing different amounts of titanium dioxide nanoparticles, ranging from 0.05% to 0.35% w/w, were prepared using the solution cast method. These systems were characterized by X-ray diffraction (XRD), infrared spectroscopy (FTIR), low-field nuclear magnetic resonance (NMR), thermogravimetric analysis (TG) and differential scanning calorimetry (DSC). The FTIR analysis confirmed that there was an interaction between the PCL chains and the TiO2 nanoparticles. The XRD and DSC analysis showed that the PCL crystallization was affected by TiO2 incorporation, modifying its semi-crystalline structure to a less ordered structure. When TiO2 nanoparticles were added the values of T1H and T1ρH increased for all hybrids, therefore, their addition produced a new material with less molecular mobility. In the TG analysis, it was observed that the introduction of TiO2 nanoparticles decreased the thermal resistance of PCL. In DSC analysis, the PCL/TiO2 hybrids presented a reduction in the crystallization temperature and degree of crystallinity, except for PCL hybrids containing 0.15% w/w of TiO2 nanoparticles.
Keywords:
Poly (ε-caprolactone), Dioxide Titanium, Hybrids, NMR Relaxometry
1. Introduction
The combination of organic and inorganic structures within a single material at nanoscopic level is one of the most effective approaches for producing new class of hybrids materials with advanced properties. A wide range of nanoparticles such as: clays, carbon nanotubes, graphites, polyhedral oligomeric silsesquioxane and metal oxides are currently available and they are used to prepare these systems [1] . Moreover, the uniform dispersion of these nanofillers produces a large interfacial region between the nanofiller and polymer, due to its high surface area, leading to peculiar characteristics [2] .
Thus, organo-inorganic hybrids are defined as complex materials containing both organic and inorganic constituents intimately mixed. The scale of the mixture or the degree of homogeneity may influence the properties of the hybrids, especially when the mixture of the components is adequately achieved on the nanometer scale. These new systems require a detailed characterization of their structure and molecular dynamics, as these factors influence the behavior, properties and stability of these new materials. One of the techniques that can be used to study the molecular dynamics of the polymeric systems is the nuclear magnetic resonance in the solid state through measures of protons relaxation [3] [4] .
NMR relaxometry technique has been used by several researchers to measure the nuclear relaxation times, such as: spin-lattice relaxation time in the laboratory frame, spin-lattice relaxation time in the rotating frame and spin-pin relaxation time in the laboratory frame, which gives insight into the molecular dynamics of the nanostructured systems [5] [6] [7] . The spin-lattice relaxation time in the laboratory frame promotes evaluation of the samples in the MHz scale. The spin-lattice relaxation time in the rotating frame is sensitive to the movements in the tens of kHz and the spin-spin relaxation time in the laboratory frame comes from the loss of phase coherence among nuclei in the xy plane, which affects the relaxation of the component perpendicular to the main magnetic field (Bo). The spin-lattice relaxation parameters involve changes in thermal equilibrium of spin systems and the responses of them are intrinsically related to the system’s molecular dynamics that is derived from the morphology of the system [5] [6] [7] .
Hence, the relaxation parameters are a good tool to understand the changes in the molecular interaction, the molecular dynamics of the hybrid components, the molecular domains in an organic material, the chain organization after the nanoparticles are incorporated into the polymer systems, and the dispersion of the nanoparticles in the polymer matrix. Normally, when spherical nanoparticles such as: titanium dioxide and silica are well dispersed and distributed in the polymer matrix, the proton-spin lattice relaxation times increases because of the rigid behavior of these particles in the polymer matrix [2] [8] .
In the past decades, titanium dioxide nanoparticles (TiO2) have received a fair amount of attention because of its good thermal stability, accessibility and catalytic properties. It is generally used for various applications, such as paints, coatings, plastics, papers, inks, medicines, pharmaceuticals, food products, cosmetics, implants, toothpastes and solar energy conversion, photocatalysis, UV detection, ultrasonic sensing and as a promising material in applications such as water or wastewater treatment. Its environmental compatibility, non toxicity and low price are some of its advantages [9] [10] .
Polycaprolactone (PCL) is a linear semi crystalline aliphatic polyester (~50% crystallinity), considered as a biocompatible, and bioresorbable material. Its potential use is currently being examined as biodegradable packaging materials, controlled drug release carriers and other medical applications, such as suture filaments. Moreover PCL is approved by Food and Drug Administration (FDA) for biomedical applications. The PCL has a low glass-transition temperature of -60˚C, a melting point of 60˚C, and exhibits high decomposition temperature around 350˚C. In comparison to other biodegradable polyesters, an in vivo degradation of PCL is considerably long. Another important fact is that the addition of nanofillers such as hydroxyapatite, clays, titanium oxide, graphite and silica does not affect the bioactivity of PCL. However, its low melting temperature, modulus, abrasion resistance, and its relatively high cost are the major disadvantages [11] [12] .
Most of the works that developed PCL/TiO2 nanocomposites used the sol-gel process in situ or melt mixing. The sol gel process allows obtaining the polymer chains into an inorganic network and it involves a series of reactions of hydrolysis and polycondensation from the precursor to the inorganic domain. However, there are some drawbacks of this method, such as: high cost of precursors, residual porosity and shrinkage of a wet gel upon drying [13] . The melt mixing process is a solvent free technique that utilizes heat and pressure to disperse the polymer and nanoparticle. Although, there are some limitations, as the cost of equipment, both of the components must be in the molten state and the large difference in the melt viscosity of the components difficult the mix [14] .
In this context, the present study had two main objectives the first one was to prepare PCL/TiO2 hybrids through the cast solution method, to produce a good system at the molecular level. The polymer and nanoparticles were solubilized in a solvent and applied on a glass plate using casting device14. The other objective was to use nuclear magnetic resonance relaxometry (NMR-relaxometry) to evaluate the molecular dynamic of the samples and to understand the behavior of the new material.
2. Materials
Polycaprolactone (PCL) pellets (Mw: 80,000 - 100,000 g/mol), obtained from Sigma Aldrich, was used as the polymer matrix. Titanium dioxide particles (TiO2) were supplied by DuPont (Brazil), having specific surface area of 50 mg2/g and average primary particle size of 25 nm. Chloroform was purchased from Tedia Brazil.
2.1. Preparation of hybrids
The PCL film was produced using a solvent casting technique. Briefly, the PCL granules were dissolved in chloroform at room temperature overnight with vigorous stirring to obtain a concentration of 5% w/v. The solution was poured into a glass Petri dish, which was covered and placed at room temperature for slow evaporation. The dried film was collected and vacuum dried for 48 h. Chloroform was chosen as solvent according to the PCL solubility parameter, obtained in a previous study. Solvent elimination was confirmed by disappearance of chloroform bands at 3034 cm−1, 1220 cm−1, 774 cm−1 and 680 cm−1 using infrared spectroscopy.
The PCL/titanium dioxide hybrids were also prepared through the solvent casting technique, using chloroform as the solvent. The solutions of PCL and titanium dioxide were stirred separately at room temperature for 24 hours to prepare the nanomaterials with different titanium dioxide ratios, ranging from 0.05% w/w to 0.35% w/w in relation to PCL concentration. The titanium dioxide dispersions were subjected to ultrasound for one hour. The flasks with the isolated solutions were sealed with glass cover and stirred at room temperature for 24 h. After that, the solutions were mixed and left for 24 h under stirring. The resulting mixture was poured into Petri dishes and kept at room temperature. The hybrids films were further dried under vacuum for 48 h and all the samples were stored in desiccators until use [6] [15] .
2.2. Characterization Techniques
2.2.1. FTIR Analysis
The infrared spectra were recorded with a Nicolet, Magna FR 760, Fourier transform infrared (FTIR) spectrometer capable of both mid-infrared (mid-IR) and far-infrared (far-IR) measurements, was used to spectroscopically examine inorganic filler, polymer and hybrids. An integral Diamond Attenuated Total Reflectance (ATR) accessory was used for all measurements. Far-IR Attenuated Total Reflection (ATR) measurements were made using a built-in Diamond ATR accessory, solid substrate beamsplitter and standard IR source. Mid-IR ATR measurements were made using a built-in Diamond ATR accessory, potassium bromide (KBr) beamsplitter and standard IR source. All spectra were obtained using 64 scans at 4 cm−1 resolution; total analysis time was three minutes per sample. The data were collected and processed using Thermo Scientific™ OMNIC™ software. For the TiO2 and PCL enough powder was placed onto the Diamond surface to cover it (1 to 3 miligrams) and the pressure device used to force the sample into contact with the Diamond crystal. The hybrids films were placed over the Diamond surface and pressure applied in the same manner as the powder samples.
2.2.2. X-ray Diffraction
The crystalline structure of the PCL and PCL/TiO2 hybrids were investigated by X-ray diffraction (XRD) using a Rigaku D/Max 2400 diffractometer, with nickel-filtered CuKα radiation of wavelength 1.54 Å, at room temperature. The 2θ scanning ranged from 2˚ to 70˚, with 0.02˚ steps, operated at 40 KV and 30 mA. The degree of crystallinity of the samples was calculated from the integrated area of X-ray diffraction data, using the Ftk software, for which were assumed Gaussian profiles for crystalline and amorphous peaks. Linear background correction was applied separately to the observed peaks before obtain the area under each peak. The areas under the crystalline and amorphous phase were determined in arbitrary units and the degree of crystallinity (Xc) was obtained using the following relationship (Equation (1)) [2] [6] [15] .
(1)
where Ia and Ic are the integrated intensities corresponding to the crystalline and amorphous phases.
2.2.3. NMR relaxation measurements
All measurements of spin-lattice relaxation times (T1H and T1ρH) were performed using a low-field NMR spectrometer, Resonance Maran Ultra 23, operating at 23.4 MHz (for protons) and equipped with an 18 mm variable temperature probe. The pulse sequence used for T1H determination was an inversion-recovery (recycle delay 180˚-t-90˚ acquisition). The 90˚ pulse, 4.6 μs, was calibrated automatically by the instrument’s software. The amplitude of the FID was sampled for twenty τ data points, ranging from 0.1 to 5000 ms, with four scans each and 5 s of recycle delay. The equipment’s precision is ±2%. The relaxation values were calculated employing the following equation (Equation (2)). The temperature of the analysis was 25˚C. The T1H values and relative intensities were obtained by fitting the exponential data with the aid of the program WINFIT. Distributed exponential fittings as a plot of relaxation amplitude versus relaxation time were performed by using the WINDXP software [5] [15] .
(2)
where, Mo is an equilibrium value, Mz is a time period during which spin-lattice relaxation occurs causing Mz to go from value of −Mo through zero to its equilibrium value of Mo, τ is time period delay and T1 is a spin-lattice relaxation time [5] [15] .
The T1ρH values were measured with ordinary spin-lock pulse sequencing, with was 90˚ x-(pin-lock pulse) y-(acquisition). The amplitude of the FID was sampled for 32 τ data points, ranging from 25 to 100,000 µs, with four scans each and 5 s of recycle delay. The T1ρH values and relative intensities were obtained also by fitting the exponential data with the aid of the WINFIT program and the distributed exponential fitting of plots of relaxation amplitude versus relaxation time was performed by using the WINDXP software. The spin-lock field was 12.5 kHz [2] [16] .
The Equation (3) is used to calculate the T1ρH values:
(3)
where, y is the total magnetization intensity; Y0 is the intensity of the magnetization at the initial time; Ai is the time constant; X is the signal weight at the initial point; X0 is the signal weight at the initial time and t1 is time interval between 180˚ and 90˚ pulses [5] .
2.2.4. Thermal Analysis
The thermal properties of PCL and its hybrids were investigated using a Rigaku TAS 100 differential scanning calorimeter. Dry nitrogen gas with a flow rate of 20 ml/min was purged through the cell during all measurements and thermal treatments, the instrument having been calibrated with an indium standard. The thermograms were recorded between -70˚C and 150˚C, with heating rate of 10 ˚C/min-1. The analysis involved the first heating from -70˚C and 150˚C followed by fast cooling (100 ˚C/min-1), followed by another heating cycle of 10 ˚C/min-1, from -70˚C and 150˚C. The fraction Xc % of material crystallized after an interval t was evaluated by the ratio of the crystallization area at the time, t, over the total area, according to the Equation (4), and the crystallinity degrees (Xc) were determined by measuring the enthalpy of fusion of the PCL in the crystalline state, using the literature data of 139.6 Jg-1 [2] [16] :
(4)
The Thermogravimetric analysis (TGA) was carried out on TA instruments Q500 (USA) apparatus from 25˚C to 500˚C under nitrogen flow (50 mL/min) at 10 ˚C/min heating rates [2] [16] .
3. Results and Discussion
3.1. Hybrids’ Structural characterization
The chemical structure of the PCL/TiO2 hybrids can be identified by FTIR. Consequently, this technique is widely used to establish the formation of new materials. In addition, an infrared analysis in the distant region is useful for inorganic studies since the stretching vibrations and angular deformation between organic/inorganic compounds occurs at frequencies lower than 650 cm-1 [17] .
The FTIR spectra of the PCL/TiO2 hybrids are shown in Figure 1 and Figure 2. In Figure 1, the two narrows signals located at 2870 cm−1 and 2954 cm−1 are attributed to C-H stretching vibrations of the PCL’s hydrocarbon and the narrow peak centered at 1734 cm−1 is derived from the stretching vibration of the PCL`s carbonyl groups (C=O) [18] . The peaks around of 850 cm−1 and 1125 cm−1 correspond to the Ti-O-Ti and Ti-O-C stretching, respectively [19] [20] .
The FTIR spectra of the hybrids formed by PCL and TiO2 (Figure 2) presented the characteristic signals of TiO2 in the far infrared region at 600 cm−1 and 100 cm−1. The broadband over the range of 400 - 700 cm−1 is related to bending and stretching mode of Ti-O-Ti, and the signals at 450 cm−1 and 620 cm−1 are due to the Ti-O-Ti bond of rutile spectrum [21] [22] . Besides that, the
Figure 1. The FTIR spectra of PCL/TiO2 hybrids, in the mid region.
Figure 2. The far FTIR spectra of PCL/TiO2 hybrids.
FTIR in the far region is able to distinguish the titanium dioxide anatase from titanium dioxide rutile. The titanium dioxide anatase shows peaks at 630 cm−1, 510 cm−1 and 140 cm−1 and the titanium dioxide rutile presents peaks at 600 cm−1 and 450 cm−1 [23] . The FTIR analysis confirmed the presence of titanium dioxide rutile in the samples.
Moreover, in hybrids systems the broader bands in the region of 450 cm−1 and 915 cm−1 can be related to the TiO2 vibrations, indicating that there was an interaction between the PCL chains and the nanoparticles [18] .
3.2. XRD Analysis
The hybrid materials were submitted to wide-angle X-ray diffraction measurement and the XRD curves are shown in Figure 3. The XRD technique is based on the elastic scattering of X-rays from structures that have long-range order. It
Figure 3. XRD curves of TiO2 and PCL/TiO2 hybrids.
is an efficient analytical technique to identify and characterize crystalline materials. The spectra of TiO2 exhibited sharp signals, indicating its crystalline nature. Sharp signals signify good crystallinity of nanoparticles [24] [25] . The X-ray diffraction showed that the TiO2 nanoparticles were a mixture of anatase and rutile form. The TiO2 nanoparticles in the anatase form presented diffractions peaks at 36˚, 54˚ and 57˚, while the TiO2 in the rutile form presented peaks at 29˚, 42˚ and 45˚ [26] .
Figure 3 also shows the diffratograms for PCL/TiO2 hybrids. The strong and sharp signals located at 21.3˚ and 23.8˚ are attributed to the [110] and [200] crystallographic planes of the PCL orthorhombic crystal, respectively [6] [15] [16] . From the X-ray diffraction spectra, it was observed that the incorporation of TiO2 nanoparticles did not affect the crystalline structure of PCL because its strong and sharp signals were maintained after the TiO2 introduction. These results are in agreement with the work of Nandagopal et al. (2016) [27] , where it was also observed that a higher concentration of titanium dioxide nanoparticles reduced the PCL crystallinity.
The PCL/TiO2 hybrids containing 0.25% and 0.35% w/w of TiO2 showed an increase in the intensity of the diffraction peaks related to PCL when compared to hybrids containing 0.05% and 0.15% w/w of TiO2. Consequently, the increase in TiO2 concentration may have modified the PCL crystallization pattern [18] [28] . Nevertheless, nonappearance of any new peak in the plots for the hybrids shows that no new phase was formed during the process of synthesis.
The crystallinity degree of all hybrids developed was obtained by curve fitting to calculate the area of each peak. Linear background correction was applied separately to the observed peaks before obtain the area under each peak, for which it was assumed a Gaussian profile. The crystalline values for PCL and PCL/TiO2 hybrids are shown in Table 1.
Table 1 shows that the incorporation of TiO2 nanoparticles decreased the PCL crystallinity in all hybrid systems, compared to pure PCL. The concentration of
Table 1. Crystalline values for PCL and PCL/TiO2 hybrids.
0.35% of TiO2 showed a major reduction in the PCL crystallinity. Probably, the TiO2 nanoparticles hindered the PCL crystallization, leading to some changes in the semi-crystalline PCL structure, resulting in a less ordered compound.
3.3. NMR Measurements
As mentioned before, the NMR relaxometry can be used to study the molecular dynamics of the new systems. The proton relaxation times are very sensible to molecular motions, in different frequency ranges. The spin lattice relaxation time, in the laboratory frame, T1H, detects the fast molecular motions, in the MHz scale, and the domains between 25 to 50 nm. The spin lattice relaxation time, in the rotating frame, T1ρ, detects the slow molecular motions, in the kHz scale, between 10 to 50 kHz and shows that the material is homogenous in the range of 4 to 25 nm [5] [6] [7] .
So, the T1H provides information’s on the presence of different mobility domains, homogeneity, miscibility, interaction among the components. Since a higher value of proton spin lattice relaxation time, T1H, represents a more restrict environment, with less molecular motions. While a lower value of proton spin lattice relaxation time, T1H, represents a more flexible environment, with more molecular motions [4] [5] [7] . The spin lattice relaxation time in the rotating frame, T1ρ, provides information’s about the segmental motions and the slow molecular motions of the polymer chains. This parameter also allows observing the homogeneity of the polymer systems, since it is sensitive to the spatial proximity of the polymer chains [2] [5] .
According to Table 2 and Figure 4 the neat PCL presented two domains with different T1H values. The first domain presented T1H value around 30 ms and it is correlated to the more mobile region of PCL (amorphous region). The second domain presented values around 142 ms and it is related to the less mobile region of PCL (crystalline region) [6] [15] . Generally the semi-crystalline polymers, such as PCL, present at least two types of molecular organization: the amorphous phase, where the protons presented less relaxation time values since it has more mobility; and the crystalline phase, where the protons presented higher relaxation time values because it has less molecular mobility [2] [16] .
In Table 2, the PCL/TiO2 hybrids systems showed a higher T1H values than the neat PCL, indicating that the addition of TiO2 nanoparticle’s promoted the
Figure 4. Distribution curves obtained by low field NMR for PCL and PCL/TiO2 hybrids.
Table 2. Proton spin-lattice relaxation times of PCL and PCL/TiO2 hybrids determined by low field NMR, with 2% error.
formation of a new material with less molecular mobility of the polymer chains due to the formation of newer and strong interactions between the TiO2 nanoparticles and the PCL chains, increasing its rigidity. This may occur because of the formation of the new molecular rearrangement of the PCL chains.
In addition, the increase of TiO2 concentration did not show a significant difference in the T1H value, suggesting that there was no change in the molecular dynamics, up to 0.25% concentration of TiO2 nanoparticles. However, with 0.35% of TiO2 nanoparticles in the PCL matrix there was a slight reduction in T1H value and it can indicate a phase separation. Since a higher concentration of TiO2 nanoparticles may hinder its dispersion in the polymer matrix and did not change the PCL molecular mobility.
Figure 4 shows the domain distribution curves of proton spin-lattice relaxation times obtained for PCL and PCL/TiO2 hybrids. All samples presented two well defined domains, related to the domains of PCL, as described above. Consequently, the two regions maintained its molecular dynamics. The Bi-exponential analysis of the spin lattice relaxation time was used because there was a significant correlation between the measured of NMR constant (T1H) and the domain curve, confirming that the samples have two domains, when analyzed in a spectrometer operating at 23.4 MHz.
The second domain of all samples presented higher T1H values than the neat PCL, indicating that there was an increase in the PCL rigidity, in the crystalline phase, with the introduction of TiO2. However, these results are not in accordance with the results obtained by the XRD analysis. Since a decrease in the crystallinity degree of the samples should decrease de T1H values of the second domains. Besides that, the DSC analysis indicated the opposite behavior, showing higher crystallinity values with the increase of TiO2 concentration. Nevertheless, the DSC values are greater than those determined from XRD profiles, since part of the material in amorphous state at room temperature is able to crystallize during the heating process and contribute to the final degree of ordering [3] .
In our previous studies using the fast field cycling NMR relaxometry, the PCL hybrids presented three distinct environments: crystallites, rigid amorphous and flexible-amorphous regions, with three distinct spin-lattice relaxation times, T11, T12, T13. The dispersion of TiO2 nanoparticles in the PCL matrix affected with greater intensity the protons mobility in the rigid amorphous region. The rigid amorphous region represents the slower PCL chain modes [6] .
In the system with 0.05 % of TiO2 there was a great interaction with PCL since the two domains presented a peak base wider than the PCL peak base.
Table 2 and Figure 5 show the T1ρH values and the T1ρH decay for PCL and all samples, respectively. The T1ρH curves show the same pattern and their fits gave a higher value of this parameter. The T1ρH values increased for all systems, compared to pure PCL. Thus, the molecular motions of PCL chains became more restricted and promoted a reorientation of PCL chains, in the 4 to 25 nm scale, with TiO2 introduction. The T1ρH data confirmed the T1H results, indicating that the TiO2 nanoparticles restricted the PCL mobility.
3.4. Thermal degradation
Thermogravimetric analysis is commonly used to identify the maximum temperature supported by a material, and it is characterized through mass loss due to volatilization with increasing temperature. The thermal stability of PCL and PCL/TiO2 hybrids materials were studied by analyzing the TGA curves. Figure 6 show the mass loss (TG%) curves of PCL and PCL/TiO2 hybrids.
For PCL, the initial degradation temperature was 383˚C, as can be seen in Table 3. The addition of TiO2 nanoparticles decreased the initial degradation temperature and the maximum temperature degradation when compared to the neat PCL. Therefore, the TiO2 nanoparticles decreased the PCL thermal resistance. However, it can be considered that the systems containing different concentrations of TiO2 presented a good thermostability, since no mass loss occurred before 370˚C.
Figure 5. T1ρH decay for PCL and PCL/TiO2 hybrids.
Figure 6. Mass loss (TG%) curves for PCL and PCL/TiO2 hybrids.
Table 3. Temperature onset of degradation (Tonset) and the maximum temperature (Tmax) of PCL and PCL/TiO2 hybrids.
Figure 6 shows the results related to the thermal stability of the PCL/TiO2 hybrids. Looking at the curves achieved under a nitrogen atmosphere, it can be said that the degradability was almost not affected by the incorporation of TiO2 nanoparticles. Moreover, the decomposition seems to occur in a unique stage. Only, the onset temperature of decomposition was slightly moved to a lower temperature. In addition, the presence of TiO2 nanoparticles slightly favored the degradability and the temperature of maximum degradation was shifted towards lower values than the neat PCL.
Addition of TiO2 has displayed different effects depending on the polymeric matrix in which it is incorporated: a considerable catalytic effect in nanocomposites based in ethylene-vinyl alcohol (EVOH) copolymer or an almost null action in polypropylene. Muñoz-Bonilla et al. (2013) also verified that the presence of TiO2 nanoparticles slightly favored the degradability of the PCL matrix3.
3.5. Differential Scanning Calorimetry
The melting temperatures (Tm) of the first and second heating, and transition enthalpy (ΔH) of the first and second heating of PCL and PCL/TiO2 hybrids were investigated by DSC. Figure 7 shows the DSC curves for PCL and PCL/TiO2 hybrids. Table 4 shows the enthalpy values and the melting and crystallization temperatures (∆Hf, ∆Hc; Tm and Tc), as well as the degree of crystallinity (Xc %). The glass transition temperature has not been described because the objective of the DSC analysis was to verify the influence of titanium dioxide nanoparticles in the crystallization process.
Figure 7. DSC curves of PCL and PCL/TiO2 hybrids, second heating.
Table 4. Transition temperatures and enthalpies obtained in the second and third heating cycles (DSC) of PCL and PCL/TiO2 hybrids.
The pure PCL showed a ΔHc of 71 J/g while PCL/TiO2 0.05% hybrids showed a ΔHc of 51 J/g, indicating a reduction in the enthalpy value of crystallization. The addition of 0.05%, hindered the crystallization process by drastically lowering the related enthalpy of crystallization. This system also showed a decrease in the ΔHm, which could be related to a restriction in the PCL crystallization kinetics. Probably the multiple interactions formed in the organic-inorganic hybrids, using 0.05% of titanium dioxide, caused a highly restricted segmental motion, hindering crystallization [2] .
However, the hybrids of PCL with 0.15% of TiO2 nanoparticles showed a ΔHc of 73 J/g, indicating that this nanoparticles concentration increased the enthalpy value of crystallization.
The PCL/TiO2 hybrids presented a reduction in the crystallization temperature, in the enthalpy of crystallization and in the melting enthalpy, except for the system with 0.15% w/w of TiO2 nanoparticles, compared to the neat PCL. So, the TiO2 nanoparticles interfered in the crystallization process. The melting temperatures of the hybrids systems were higher than the neat PCL. The degree of crystallinity was also lower than the PCL, except for the system containing 0.15% w/w TiO2, indicating that the TiO2 particles restricted the PCL mobility. Consequently, the 0.15% w/w concentration was able to distribute between the PCL chains and act as nucleating agent for the crystallization process, increasing the PCL crystallinity.
Bajsić et al. (2014) also demostrated that the melting point of the PCL/TiO2 composites was slightly higher with the increase of TiO2 concentration. When the content of TiO2 nanoparticles increased the crystallization temperature of the composites decreased. Only in PCL/TiO2 composites prepared with 2 wt% of TiO2 particles the crystallization temperature increased [29] . It was observed the same pattern for the nanocomposite containing 0.35% of TiO2.
Excluding the results of crystallinity calculated for the PCL sample with 0.15% of TiO2, the XRD analysis showed a decreasing trend in the crystallinity degree with the increase of TiO2 content, whereas the DSC indicated the opposite behavior, showing an increase in the values of crystallinity with the increase of TiO2 concentration. Nevertheless, the crystallinity values determined by DSC are more accurate than those determined from XRD profiles, since part of the material in amorphous state at room temperature is able to crystallize during the heating process and contribute to the final degree of ordering [3] .
4. Conclusion
In this study, the PCL/TiO2 hybrids were successfully prepared by solvent cast technique. It was possible to produce homogenous PCL/TiO2 hybrids, by solvent cast technique, with nanoparticles effectively dispersed. The FTIR analysis indicated that there was an interaction between the PCL chains and the TiO2 nanoparticles. The XRD analysis showed an increase of the amorphous halo and this can be the result of the interaction of the TiO2 with the PCL chains. The PCL/TiO2 hybrids systems showed a higher T1H values than the neat PCL, indicating that the addition of TiO2 nanoparticle’s promoted the formation of a new material with less molecular mobility. The T1ρH data confirms the T1H results, indicating that the TiO2 nanoparticles restricted the PCL mobility. In the thermal degradation analysis, it is observed that the TiO2 nanoparticles decreased the PCL thermal resistance. In DSC analysis, the PCL/TiO2 hybrids presented a reduction in the crystallization temperature, in the enthalpy of crystallization, in the melting enthalpy and crystallinity degree, with the exception of 0.15% w/w of TiO2 nanoparticles. These hybrids have a great potential for applications in many fields, especially in the biomedical and pharmaceutical area, since they are formed by biocompatible and biodegradable polymer, PCL, and titanium dioxide nanoparticles, which is used as pharmaceutical excipient.
Acknowledgements
The authors are grateful to CAPES, CNPQ and FAPERJ for all grants.
Cite this paper
de S. B. Monteiro, M.S. and Tavares, M.I.B. (2018) The Development and Characterization of Polycaprolactone and Titanium Dioxide Hybrids. Advances in Nanoparticles, 7, 11-27. https://doi.org/10.4236/anp.2018.71002
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