https://doi.org/10.52131/jmps.2022.0301.0022 14 Journal of Materials and Physical Sciences Volume 3, Number 1, 2022, Pages 14 - 21 Journal Homepage: https://journals.internationalrasd.org/index.php/jmps Synthesis and Characterization of CNT/PVA Nanocomposites for Electrical, Thermal and Morphological Properties Gulfam Nasar1*, Uzma Khalil2, Muhammad Saleem Khan3, Qaisar Nadeem4 1 Department of Chemistry, Balochistan University of Information Technology, Engineering and Management Sciences, Quetta, Pakistan 2 Jinnah College for Women, University of Peshawar, Pakistan 3 National Center of Excellence in Physical Chemistry, University of Peshawar, Pakistan 4 Department of Chemistry, University of Zurich, Winterthurerstr, 190, 8057 Zurich, Switzerland ARTICLE INFO ABSTRACT Article History: Received: February 15, 2022 Revised: April 12, 2022 Accepted: June 28, 2022 Available Online: June 29, 2022 The goal of the current work is to bring a helpful substance to nanoscience and nanotechnology that might be a "problem solver" for ion storage. Carbon nanotubes/ PVA nanocomposites were prepared in five concentrations in aqueous medium following film formation. The resulting nanocomposites were characterized using “AC Impedance Spectroscopy, Differential Thermal Analysis, Thermal Gravimetric Analysis / (TG/DTA) and Scanning Electron Microscopy (SEM)”. Ionic conductivity of the nanocomposites was determined from impedance spectroscopy. CNT/PVA nanocomposites exhibited lower conductivity as compared with CNT or PVA separately. TG/DTA graphs exhibited a regular pattern, showing an increase in the thermal stability. Morphology of the prepared samples as shown by SEM reveals a favourable polymer-filler morphological arrangement at the interphase, which is suggestive of a favourable compatibility between the polymer and the filler substance. Keywords: PVC Carbon nanotubes Nanocomposites Ionic conductivity AC Impedance TGA SEM © 2022 The Authors, Published by iRASD. This is an Open Access article under the Creative Common Attribution Non-Commercial 4.0 *Corresponding Author’s Email: gulfam.nasar@buitms.edu.pk, gulfamnasar@gmail.com 1. Introduction The discovery of numerous carbon nanostructures, metal nanoparticles, and other unique structures has spurred advancements in nanoscience and nanotechnology since the second half of the twentieth century (Kakani, 2004). Metal nanoparticles and carbon nanostructures have numerous applications in a variety of sectors thanks to their distinctive thermal, electrical, magnetic, and optical properties (Masciangioli & Zhang, 2003). These materials can be used individually or as distributed media in matrices, host materials, and polymer nanocomposites (Safadi, Andrews, & Grulke, 2002). For a variety of purposes, efforts are being undertaken to find the material that is best suited. Although nanoparticles and nanocomposites have provided solutions to many contemporary challenges (Nicolais & Carotenuto, 2005), there is still unmet demand in this area, leading to the creation and development of fresh materials every day. The current study is yet another trial to add to the valuable and modern material that will serve the scientists working in the cotemporary field. 2. Experimental 2.1. Chemicals Used Poly vinyl alcohol (PVA) 125,000 g / mol, Nitric acid, Multi Walled Carbon Nano Tubes Cetyl Trimethyl Ammonium bromide ‘CTAB’, De-ionized water of Millipore grade was used as solvent. https://journals.internationalrasd.org/index.php/jmps mailto:gulfam.nasar@buitms.edu.pk mailto:gulfamnasar@gmail.com Gulfam Nasar, Uzma Khalil, Muhammad Saleem Khan, Qaisar Nadeem 15 2.2. Synthesis of CNT/PVA Nanocomposites 5 w/w % stock solutions of PVA and required reagents were made. The same were used to prepare reagent solutions for synthesis of nanocomposites (Sankar, Kumar, & Rao, 2004). The CNTs were functionalized, with constant stirring with water. The contents were transferred to a glass tube and were ultra-sonicated for two hours. 5 ml solution of 5 molar nitric acid was dripped into the contents and thus subsequent mix was subjected to refluxing process 12 hours at 120 ̊C. The functionalized CNTs were filtered and washed until pH 7 was obtained. The CNTs were suspended in de-ionized water with the help of CTAB whose 75 mg were dissolved in water before 10 mg CNTs were introduced to it. After dilution to 100 ml, ultra-sonication was performed for 8 hours at 60 ̊C (Laachachi et al., 2009). To make CNT-PVA nanocomposites, the fractions of both the solutions were mixed in appropriate ratios using dilution formula. Magnetic stirring was carried out for 24 hours and films were grown in petri dishes. Appropriate sizes and shapes were obtained from the generated films for characterizing (Rajendran & Bama, 2010). 3. Characterization The samples were subjected to the following characterization techniques. 3.1. Electrical Properties “AC Impedance Analyzer PGSTAT 302, manufactured by Autolab, Netherland” was used to study electrical behavior of CNT-PVA nanocomposites (Baskaran, Selvasekarapandian, Kuwata, Kawamura, & Hattori, 2007). 1 square centimeter sample piece from each composition was subjected to a three-probe measuring system of AC Impedance analyzer (Ulaganathan, Pethaiah, & Rajendran, 2011). The third electrode is used as a reference electrode in addition to two working electrodes having area of its cross section 1×10−4 cm2. The measuring frequency was set 1 Hz–30 KHz, while 10 mV amplitude was used at room temperature. 3.2. Thermal Analysis 5-8 mg sample of each composition was analyzed for thermal properties using “Diamond TG/DTA machine manufactured by Perkin Elmer Instruments, USA” (Rajendran, Kesavan, Nithya, & Ulaganathan, 2012) with a uniform heating rate of 5 ̊C/minute from 30- 600 0C (Rimez et al., 2008). 3.3. Morphological Analysis “Scanning Electron Microscope SEM SJ-6490LVMA manufactured by JEOL, Germany” was used to characterize morphology and dispersion of the CNT within the polymer matrix (Kim & Kim, 2006). The appropriate sizes of the samples of polymer nanocomposites were gold-coated utilizing sputter coater machine before SEM analysis. For this purpose voltage of 5-20 kV was used while the resolution was kept from 500-100000X. The most suitable voltage and resolution was used to take micrographs of the CNT-PVA nanocomposites. 4. Results and Discussion 4.1. AC Impedance of PVA/ CNT Composites CNT-PVA nanocomposites were characterized for electrical properties. A representative Nyquist plots is shown in figure 1. Semi-circular path exhibited by the CNT- PVA nanocomposite is attributed to the conducting region of the nanocomposite. CNTs being light-weight material exhibit low density and show a commendable degree of conductivity (Zhao et al., 2008). They exhibit anisometric behavior that is quite significant in transforming a transition between non-conducing to conducting behavior by the incorporation into a polymer matrix. The individual surface properties of the components of Journal of Materials and Physical Sciences 3(1), 2022 16 the nanocomposite also play a major role in characterizing the electrical properties of the nanocomposite. Detention of PVA over the interfaces of CNTs also plays a role in defining the electrical conductivity of the nanocomposite. The conductive behavior of CNT-PVA nanocomposites is depicted from figure 2 that shows the circuit diagram of the prepared sample. The obtained results comply with previous findings (Nam et al., 2012). The current study focuses more on the lower concentrations of the CNT unlike the earlier reported work, focused on higher concentrations of CNT (Khan, Shakoor, & Nisar, 2010; Wang & Qiu, 2011). This aspect marks this study significant in understanding in terms of greater compatibility and economic feasibility. In figure 2, in order to obtain a good fit, an additional circuit component; Warburg impedances is added (Khan et al., 2010). The Warburg element can be defined as “a common diffusion circuit element that is used to model or simulate semi-infinite linear diffusion, that is, unobstructed flow to a large planar electrode.” The "diffusion-limited processes" linked to the ionic conductivity of the CNT-PVA nanocomposite is simulated using this component (Zamri, Zein, Abdullah, & Basir, 2011). 0 1000 2000 0 200 400 600 -Z '' / K  Z' K  Figure 1: AC Impedance Spectrum of CNT-PVA Nanocomposite Figure 2: Circuit diagram of the CNT-PVA nanocomposite Bulk resistance (Rb) of the nanocomposites was figured out from the frequency of a high range of Nyquist plot (Abraham, Alamgir, & Hoffman, 1995; Bhattacharyya, Salvetat, & Saboungi, 2006). One can calculate ionic conductivity (σ) of the composite from Eq. (1). Gulfam Nasar, Uzma Khalil, Muhammad Saleem Khan, Qaisar Nadeem 17 σ = l / ARb (1) ‘A’ shows the area of electrode (1 cm2) and ‘l’ depicts thickness of the CNT-PVA nanocomposite sample film (0.001 cm). The values calculated through Eq (1), are shown in Table 1. The same results are displayed in graphical form in figure 3, indicating that the ionic conductivity increases with an increasing amount of CNT in the nanocomposite. This increase is attributed to mobility changes and carrier concentration of the CNT in the matrix of PVA. Due to the decrease in the inter-particulate distances, this change is enhanced further in the higher concentrations of CNT. a decreased distance between the particles ensures enhanced hopping activity resulting in overall ionic conductivity augmentation (Rajendran, Bama, & Prabhu, 2010). Table 1 Bulk Resistance and Ionic Conductivity of CNT-PVA Nanocomposites No. Bulk Resistance Rb/Ω Ionic Conductivity σ/S cm-1 1 4160.10979 2.4E-06 2 4064.04392 2.46E-06 3 3760.06404 2.66E-06 4 3319.64776 3.01E-06 5 2099.26807 4.76E-06 0 2 4 6 0.000002 0.000003 0.000004 0.000005 Io n ic C o n d u c ti v it y ( )/ S c m -1 Mass of the filler /mg Figure 3: Ionic Conductivity of the CNT-PVA Nanocomposite Figure 4: Circuit Diagram of the Developed Composites Journal of Materials and Physical Sciences 3(1), 2022 18 4.2. Thermal Analysis of PVA /CNT Composites Figure 5 shows a TGA thermogram of the generated samples of PVA/CNT nanocomposites showing weight loss as a temperature-function. PVA decomposes in two phases and is stable up to 265oC (Ma, Tang, & Kim, 2008). Around 350oC is the temperature at which the PVA side chain decomposes, while 450oC is the temperature at which the PVA backbone degrades (Nasar, Khan, & Khalil, 2010; Sriamornsak & Kennedy, 2006). According to the TGA for figures 87–89, weight loss for PVA/CNT 1 mg, PVA/CNT 3 mg, and PVA/CNT 5 mg happened in three stages. First step weight loss was from 11% to 14%, attributed to vaporization of the water content. Second phase of loss in mass was 53 to 56 %, due to combustion, up to 352oC. A weight loss of around 20% occurred mainly due to decomposition of side chains and degradation of PVA to up to 600oC. DTA also supports the results shown in figures 91-96. Figure 5 compares TGA, and Figure 6 displays DTA for various compositions. Results indicate that the thermal stability somewhat increases as CNT concentration rises from 1 mg to 5 mg. The conclusion is also supported by a comparison of the degradation temperatures for various compositions. Figure 5: TGA of A: PVA/CNT 1mg, B: PVA/CNT 3mg, C: PVA/CNT 5mg 0 100 200 300 400 500 600 W e ig h t % Temperature o C A B C Gulfam Nasar, Uzma Khalil, Muhammad Saleem Khan, Qaisar Nadeem 19 Figure 6: DTA of A: Pure PVA/CNT 1mg, B: Pure PVA/CNT 3mg, C: Pure PVA/CNT 5mg 4.3. Scanning Electron Microscopy Samples of various compositions of CNT/ PVA nanocomposite were analyzed for assessing the morphology of nanocomposites between 5 kV and 20 kV. Figure164 displays a network of functionalized CNTs with uniform thickness, while figure 7 shows the CNT micrograph at X37000. The particular scam of the particular conductivity. It is noteworthy that nearly all CNTs have the same diameter, which is between 30 and 45 nm. Figure 7: SEM Image of the Carbon Nanotube, Showing a Mesh/ Network of CNT 0 100 200 300 400 500 600 M ic r o v o lt s Temperature o C A B C Journal of Materials and Physical Sciences 3(1), 2022 20 5. Conclusion 1. PVA/ CNTs nanocomposites with five different concentrations of nanocomposites were synthesized in solution form which were converted to films. 2. Thermogravimetric/Differential Thermal Analysis (TG/DTA), AC Impedance Spectroscopy, and scanning electron microscopy were used to characterise the nanoparticles in detail (SEM). 3. The fillers created homogenous nanocomposites by being evenly distributed throughout the matrix. Under the microscope, the filler is distributed uniformly throughout the matrix according to the surface morphology. 4. Using SEM, the size of the nanoparticles was examined, and it was observed that the diameter of CNT ranged from 30 to 50 nm. 5. Films displayed a highly smooth surface topography and uniform morphology. However, the matrix's embedded particles could be seen and their sizes were determined. 6. It was discovered that the ionic conductivity of all the produced nanocomposites ranged from 10-6 to 10-4 Scm-1. 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