Thermal Behavior with Mechanical Property of Fluorinated Silane Functionalized Superhydrophobic Pullulan/Poly(vinyl alcohol) Blends by Electrospinning Method

Karim, Mohammad Rezaul; Islam, Md. Shahidul

doi:https://doi.org/10.1155/2011/979458

Journal of Nanomaterials

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Polymer Nanocomposite Processing, Characterization, and Applications 2011

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Research Article | Open Access

Volume 2011 | Article ID 979458 | https://doi.org/10.1155/2011/979458

Thermal Behavior with Mechanical Property of Fluorinated Silane Functionalized Superhydrophobic Pullulan/Poly(vinyl alcohol) Blends by Electrospinning Method

Mohammad Rezaul Karim¹and Md. Shahidul Islam²

Academic Editor: Gaurav Mago

Received14 Jun 2011

Accepted19 Aug 2011

Published24 Oct 2011

Abstract

Fluorinated silane functionalized superhydrophobic pullulan/poly(vinyl alcohol) (PULL/PVA) blend membrane with water contact angle larger than 150° has been prepared by the electrospinning method. The morphology, thermal stability, and mechanical property of the membranes are characterized using scanning electron microscopy (SEM), thermogravimetric analysis (TGA), and ZWICK materials testing machine, respectively. Interactions between PULL and PVA and PULL/PVA blends with perfluorooctyltriethoxysilane (PFOTES) of the membranes are analyzed using differential scanning calorimetry (DSC) and Fourier transform infrared (FTIR). Contact angles and water drops on the surface of the membrane are measured by video microscopy. The study shows that the addition of minor quantity of PVA with PULL results in improvement in thermal stability and mechanical property (tensile strength) of the PULL membranes.

1. Introduction

The wettability of a solid surface is an interesting property of a material and is described as the contact angle between a liquid and a solid surface. When the contact angle between water and a solid surface is larger than 150°, this solid surface is called a superhydrophobic surface [1]. Superhydrophobic surfaces are widely found in nature. For example, the surface of a lotus leaf is observed to be an array of nanoscale buds [2]. Water drops on the surface of the leaf tend to slide down, rendering its self-cleaning property. The surfaces which mimic “lotus effect” have triggered extensive interests for their potential applications involving water repellency, self-cleaning, and antifouling properties [3–6]. Generally, the hydrophobicity of surfaces depends on both their chemical composition and surface geometrical structure [7]. In terms of chemical composition, hydrophobicity can only be increased by introducing a component with low surface energy such as fluorinated methyl groups. However, this method to increase hydrophobicity is limited.

The maximum contact angle that can be reached by coating fluorinated methyl groups onto a flat solid surface is only 120°, which can be hardly called superhydrophobic [8]. Therefore, a hierarchical structure is introduced into the solid surface to achieve superhydrophobicity. A number of methods have been used to make a hierarchical superhydrophobic surface including phase separation [9], electrochemical deposition [10], chemical vapor deposition [11], crystallization control [12], photolithography [13], assembly [14], sol-gel methods [15], solution-immersion methods [16], and array of nanotubes/nanofibers [17, 18].

Electrospinning is a simple but versatile method to produce continuous fibers with diameters ranging from nanometer to submicron scale. Superhydrophobic surfaces can be obtained through this process by controlling the surface roughness under appropriate conditions [19, 20]. Superhydrophobic polystyrene nanofibers were electrospun by either using various solvents [8] or adding room temperature ionic liquid [21]. Cellulose triacetate fibrous mat [22] and poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) fibrous surfaces [23] are fabricated using electrospun fibers followed with plasma treatment. Electrospun nanofibers from the blending solution of fully hydrolyzed medium molecular weight poly(vinyl alcohol) and high-molecular-weight poly(vinyl alcohol) with montmorillonite were fabricated [24].

Pullulan is a natural polymer with excellent biocompatibility. The use of natural polymer has created tremendous interest recently, for example, as proteins in biotechnological materials and biomedical applications [25]. However, only few reports are available in the literature regarding superhydrophobic PULL membrane prepared by electrospinning. Pullulan’s solubility can be controlled or provided with reactive groups by chemical derivatization. Due to its excellent properties, pullulan is used as a low-calorie ingredient in foods, gelling agent, coating and packaging material for food and drugs, binder for fertilizers, and as an oxidation-prevention agent for tablets. Other applications include contact lenses manufacturing, biodegradable foil, plywood, water solubility enhancer, and for enhancing oil recovery [26–29].

Poly(vinyl alcohol) (PVA) is a semicrystalline hydrophilic polymer with good chemical and thermal stability. It is a highly biocompatible and nontoxic polymer and it can be processed easily; it also has high water permeability. PVA can form physical gels in various types of solvents which lead to the use of PVA in a wide range of applications in medical, cosmetic, food, pharmaceutical, and packaging industries [30–36].

Polymer blending constitutes a very useful method for the improvement or modification of the physicochemical properties of polymeric materials. An important property of a polymer blend is the miscibility of its components because it affects the mechanical properties, the morphology, and the permeability and degradation. Polymer blends are physical mixtures of structurally different polymers or copolymers that interact with secondary forces with no covalent bonding [37], such as hydrogen bonding, dipole-dipole forces, and charge-transfer complexes for homopolymer mixtures [38–40].

In our previous report, we prepared fluorinated silane functionalized pullulan superhydrophobic membrane using electrospinning technique [41]. In this study, fluorinated silane functionalized superhydrophobic PULL/PVA blend membranes are made to enhance the thermal stability and mechanical property (tensile strength) of PULL membranes by applying the same technique.

2. Experimental

2.1. Materials

Pullulan is a food grade preparation (PF-20 grade) from Hayashibara Biochemical Laboratories Inc. (Okayama, Japan), PVA with = 1,700 (fully hydrolyzed, degree of saponification = 99.9%) was obtained from DC Chemical, Seoul, Republic of Korea and perfluorooctyltriethoxysilane (PFOTES) is purchased from Aldrich Chemical Company. Doubly distilled water is used as a solvent to prepare all solutions.

2.2. Preparation of PULL/PVA/PFOTES Blend Solutions

The PULL/PVA solutions (total polymer concentrations are 9 and 12 wt.%) with 80/20 mass ratio were prepared in doubly distilled water at 80°C temperature under magnetic stirring for 2-3 h. The PULL/PVA/PFOTES blend solutions were prepared by mixing of the PULL/PVA solutions with 1 wt.% of PFOTES with gently stirred for further 24 h. The formed solutions were then used for the preparation of membranes using electrospinning technique.

2.3. Membrane Preparation by Electrospinning

During electrospinning, each solution was continuously supplied using a syringe pump with a speed of 0.04 mL/h through a 25G needle producing a Taylor cone. A high power voltage (15 kV) was supplied to the solution with a tip-to-collector distance of 15 cm. Membranes were collected on electrically grounded aluminum foil placed at a vertical distance to the needle tip. Trace amount of PFOTES does not affect the electrospinnability of PULL/PVA blend solution.

2.4. Characterization of Membranes

The water contact angles of the membranes were measured using video microscopy. Using a microsyringe, 5 μL deionized water was dropped perpendicularly to each surface of the membranes placed on a horizontal glass sheet. Then, the images of water drops on the surface of the membranes were observed using Scalar Video Loupe (VL-11s) and analyzed using the Sigma TV II program. Membranes were also characterized with FTIR (IFS 120HR, Bruker) and DSC (model Q-10) from TA instruments, USA. The morphology, thermal stability, and mechanical property (tensile strength) of membranes were observed with a field-emission scanning electron microscope (JEOL, model JSM-6380) after gold coating, TGA technique (model Q-50; TA Instruments, USA), and ZWICK Z005 (ZWICK materials testing machine, Germany), respectively.

3. Results and Discussion

3.1. DSC Data of Membranes

Figure 1 illustrates the DSC thermograms of pure PULL, PVA, and electrospun PULL/PVA blend membrane with 80/20 mass ratio at a total polymer concentration of 9 wt.%. A relatively large and sharp endothermic peak is observed at about 224°C (Figure 1(a)) and is assigned to the melting temperature of pure PVA, which has a number-average degree of polymerization of 1700, which agrees very well with reported data [42]. This peak is shifted to 206.50°C with the addition of 80 wt.% PULL (Figure 1(b)), and this shifts the melting temperature to lower value; this occurred because of the addition of PULL whose melting temperature changes from 95 to 84°C (Figure 1(b)). This is because the majority of the chains are in a noncrystalline state due to the rapid solidification process of stretched chains during electrospinning. Pure PULL shows a large thermogram peak of melting transition () at 95°C (Figure 1(c)).

The interactions between PULL/PVA blending and PFOTES of membranes are investigated by DSC. Figure 2 shows the DSC thermogram of PULL/PVA/PFOTES blend membrane with 1 wt.% of PFOTES contents and 80/20 mass ratio of those two polymers at a total polymer concentration of 9 wt.%. Without PFOTES, PULL/PVA membrane shows two thermogram peaks of melting transitions () at 84°C, and 206.50°C (Figure 2(a)). These peaks are shifted to 88.5°C and 208°C with the addition of 1 wt.% PFOTES (Figure 2(b)). The DSC thermograms for the membranes show clearly the melting transitions of the PULL/PVA blend membrane, in which there are significant effects of the PFOTES content. The dramatic changes of of the composite membranes can be attributed by the introduction of CF₃ groups into heteroatom (O atom) containing hydrophobic carbon ring of PULL and hydrophobic carbon chain of PVA.

3.2. FTIR Data of Membranes

FTIR spectra give information about the structure of blend membranes studied. In Figure 3, examples of spectra of pure PULL and PULL/PVA blend membranes at 500–4000 cm⁻¹ range are shown. Pure PULL membrane exhibits identical bands as shown in Figure 3(a). Strong absorption in 850 cm⁻¹ is characteristic of the a-glucopyranoside units. Absorption in 755 cm⁻¹ indicates the presence of α-(1,4) glucosidic bonds, and spectra in 932 cm⁻¹ proves the presence of α-(1,6) glucosidic bonds. Besides, in the areas for reference and evaluated samples the frequencies are analogous [43]. Bands at 2850–3000 cm⁻¹ are due to stretching vibrations of CH and CH₂ groups and bands attribute to CH/CH₂ deformation vibrations are present at 1300–1500 cm⁻¹ range. Also very intensive, broad hydroxyl band occurs at 3000–3600 cm⁻¹ and accompanying C–O stretching exists at 1000–1260 cm⁻¹. With the addition of PVA, some absorption peaks of PULL become lower in intensity, whereas some absorption peaks at 1096 and 1447 cm⁻¹ appear and the intensity of these peaks increases with augmenting the concentration of PVA (Figures 3(b) and 3(c)). This suggests that hydrogen bonds between hydroxyl groups in PULL and hydroxyl groups in PVA could possibly play a role in the shift of the peaks. Thus, the FTIR spectroscopy supports the interactions between PULL and PVA, which are suggested above. Moreover, the absorption peaks which appeared at 1145 cm⁻¹, 1235 cm⁻¹, and 1430 cm⁻¹ are attributed to the vibrations of CF₂ and CF₃ groups in PFOTES and the absorption peaks at 700–800 cm⁻¹ are due to the vibration of Si–O groups in the silanes (Figure 4(b)). Thus, the FTIR spectroscopy supplies also evidences of possible interactions between PULL/PVA blend and PFOTES, which are suggested by DSC.

3.3. TGA Data of Membranes

Thermal stability of PULL/PVA membranes is measured using TGA in nitrogen atmosphere. Figure 5 shows TGA thermograms of different decomposition temperature with PULL/PVA mass ratios of 100/0, and 80/20. The below curve of the TGA data (Figure 5(a)) represents the pure PULL membrane and the upper curve (Figure 5(b)) is for 80/20 blend ratio of PULL/PVA. Clearly, it can be seen that higher thermal stability of the membranes could be with the addition of PVA in the PULL/PVA blend system.

3.4. Tensile Strength

Some of the fascination with the behavior of polymers comes from the large changes in the physical properties and the wide range of mechanical behaviours [44]. The tensile strength of the PULL/PVA blend membranes increases with augmenting the weight percentage of PVA, as shown in Table 1.

3.5. Water Contact Angles of Membranes

Membranes prepared by electrospinning method have much higher contact angle because of the high surface area of the formed fibers that ranges from nanometer to submicron scale. As shown in Figure 6(a), nanofibers electrospun using total polymer concentration 9 wt.% contain a large number of beads in nanometer size (500–1000 nm), whereas less number of beads containing nanofibers can be electrospun using total polymer concentration of 12 wt.%, and 9 wt.% and 12 wt.% of total polymer concentrations coupled with PFOTES applying the same parameters as shown in Figures 6(b), 6(c), and 6(d), respectively. The obtained nanofibers are ranged from 200 to 800 nm. The reason for different bead contents in each concentration is that the Rayleigh forces, which assist in bead formation, are able to overcome the viscous forces to enable the formation of beads [45]. Moreover, strong interaction between PULL/PVA blends and PFOTES is attributed to the formation of less number of beads in the fibers. The interaction between PULL/PVA blends and PFOTES can be put forward as a cause to two factors.

(a)

(b)

(c)

(d)

First, the introduction of hydrophobic CF₃ groups on the heteroatom (O atom) containing hydrophobic carbon ring of PULL and hydrophobic carbon chain of PVA and the second factor is the interaction obtained from the formation of hydrogen bonding between polar hydrogen of –OH group of PULL and PVA with O of PFOTES. Although contact angles of up to 147° (Figure 6(a)) and 142° (Figure 6(b)) can be reached by directly electrospinning of 9 wt.% and 12 wt.% of total polymer concentration solutions, respectively, the membranes can not still be considered as superhydrophobic membranes. Therefore, 9 wt.% and 12 wt.% of total polymer concentration solutions coupled with PFOTES are used to successfully prepare superhydrophobic membranes with high-contact angles of 155° (Figure 6(c)) and 152° (Figure 6(d)), respectively. Water contact angles of all samples taken in this experiment are shown in Figure 7 (data are given in Table 2). Higher contact angle of 9 wt.% of total polymer concentration than that of 12 wt.% total polymer concentration can be explained on the basis of surface roughness like lotus leaf [2] due to the more bead formation in case of 9 wt.%.

4. Conclusions

Superhydrophobic PULL/PVA membranes are prepared by electrospinning from fluorinated silane functionalized PULL/PVA blends. It is observed that both of 9 wt.% and 12 wt.% of total polymer concentration membranes can only reach contact angles lower than 150° by electrospinning of PULL/PVA blends without using PFOTES. Superhydrophobic membranes with contact angles of up to 155° and 152° can be achieved by electrospinning of 9 wt.% and 12 wt.% of total polymer concentration solutions coupled with fluorinated silane, respectively. Moreover, thermal stability and mechanical property of the PULL membranes has been enhanced with the introduction of PVA.

Acknowledgment

This project was supported by King Saud University, Deanship of Scientific Research, College of Engineering Research Center.

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Copyright © 2011 Mohammad Rezaul Karim and Md. Shahidul Islam. 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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