Thermal and mechanical properties of PVDF/PANI blends

Malmonge, Luiz Francisco; Langiano, Simone do Carmo; Cordeiro, João Manoel Marques; Mattoso, Luiz Henrique Capparelli; Malmonge, José Antonio

doi:10.1590/S1516-14392010000400007

Abstract

Poly(vinylidene fluoride)/polyaniline blends of different composition were synthesized by chemical polymerization of aniline in a mixture of Poly(vinylidene fluoride) and N,N-dimethylformamide and their thermal and mechanical behavior was investigated as a function of the polyaniline doping level and the composition using thermogravimetric analysis, differential scanning calorimetry, dynamic mechanical analysis and tensile tests techniques. The results showed the blend obtained presents a good thermal stability with low weight loss up to 300 ºC, assigned to water and solvents evaporation. The glass transition and melting point is not affected by the PANI content in the blend, showing that polymers are no miscible. The films produced present a good sustainability; however the presence of the conducting polymer in the blend increases the tensile strength and the Young modulus, while diminishes the elongation at break, as compared to pure PVDF.

PVDF; polyaniline; PVDF; thermal propriety

REGULAR ARTICLES

Thermal and mechanical properties of PVDF/PANI blends

Luiz Francisco Malmonge^I,^* * e-mail: lfmal@dfq.feis.unesp.br ; Simone do Carmo Langiano^I; João Manoel Marques Cordeiro^I; Luiz Henrique Capparelli Mattoso^II; José Antonio Malmonge^I

^IDepartamento de Física e Química, Faculdade de Engenharia, Universidade Estadual Paulista - UNESP, Campus Ilha Solteira, CEP 15385-000, Ilha Solteira, SP, Brazil

^IILaboratório Nacional de Nanotecnologia para o Agronegócio, Embrapa Instrumentação Agropecuária, CP 741, CEP 13560-970, São Carlos, SP, Brazil

ABSTRACT

Poly(vinylidene fluoride)/polyaniline blends of different composition were synthesized by chemical polymerization of aniline in a mixture of Poly(vinylidene fluoride) and N,N-dimethylformamide and their thermal and mechanical behavior was investigated as a function of the polyaniline doping level and the composition using thermogravimetric analysis, differential scanning calorimetry, dynamic mechanical analysis and tensile tests techniques. The results showed the blend obtained presents a good thermal stability with low weight loss up to 300 ºC, assigned to water and solvents evaporation. The glass transition and melting point is not affected by the PANI content in the blend, showing that polymers are no miscible. The films produced present a good sustainability; however the presence of the conducting polymer in the blend increases the tensile strength and the Young modulus, while diminishes the elongation at break, as compared to pure PVDF.

Keywords: PVDF, polyaniline, PVDF/PANI blend, thermal propriety

1. Introduction

Polyaniline (PANI) has been the subject of a good deal of attention in the last three decades mainly on account of its electrical conductivity and unique optical properties. Since the polymer is highly stable at standard conditions, there is an avenue for potential novel applications. However, if the manufacturing process depends on the polymer's melting or solution the production can be hindered, given that PANI is hardly soluble or melted. Because of this, the properties of blends of PANI with commercial polymers were investigated in order to obtain materials that combine the electrical and optical properties of the first with the mechanical properties of the second^1-19. The methods used to prepare blends and composites of PANI-conventional polymers include solution^1-4, polymerization in situ^5-7,4, fusion^8-10, emulsion^11-15, and inverse emulsion^16-19.Poly(vinylidene fluoride) - PVDF is a conventional polymer used as matrix for PANI blends. It has been widely investigated because of its good mechanical properties, chemical stability, high dielectric permittivity and unique pyroelectric and piezoelectric properties^20-22. It is a semicrystalline material with diverse crystalline forms, with at least five phases that are known as α, β, γ, δ and ε^23-26. In general the processed material is obtained in the non piezoelectric alpha phase. The behavior of PVDF/PANI blend have been recently investigated through several experimental techniques^7,10,27,28. From a general point of view, the mechanical and electrical properties of the blend depend on temperature, composition, and preparation route. In our previous work, PVDF/PANI blend were obtained by in situ polymerization of aniline in a PVDF/N,N-dimetylformamide (DMF) solution⁷. The influence of the oxidant/aniline ratio, dopant p-toluenesulfonic acid (TSA)/aniline ratio, and PVDF/aniline in the electrical conductivity of the blends were analyzed⁷. The electrical conductivity can achieve values of 1 S/cm at a 50 wt. (%) content of PANI in the blend and is stable at temperatures under the 100 ºC. As a continuation of our previous work, this study investigates the thermal and mechanical proprieties of those blends as a function of PANI content and PANI doped level, that is important to practical application

2. Experimental

2.1. Synthesis

The blends were obtained by chemical polymerization of aniline in a solution of PVDF as previously described⁷. In a typical experiment, 1.0 g was dissolved in 10 mL of DMF heated at 70 ºC and the mixture cooled at room temperature. The aniline (0.5 g) was added into this solution under stirring. A 20 mL of a solution of 1.22 g ammonium persulfate and 4.28 g TSA in DMF, and 44.5 mL of chloroform were slowly added into the mixture. The polymerization reaction was allowed to proceed at room temperature for 2 hours under stirring. After that time, the blend was precipitated by adding distilled water, the solid was filtered and washed with distilled water and aqueous solution of TSA 0.1 M and then dried under dynamic vacuum for 24 hours. In the sequence the blend was maintained heated at 70 ºC for an additional period of 24 hours. Deprotonation was performed keeping the material in a 0.1 M aqueous solution of ammonium hydroxide for 16 hours at room temperature to produce the blend in the dedoped form. The reprotonation was performed by dipping the material into an HCl aqueous solution of 0.05 and 1.0 M, keeping the system under stirring for 30 minutes. After that, the blend was taken out of the acid solution, and dried under dynamic vacuum for 24 hours at room temperature. This procedure produced a blend with 22,4 wt. (%) of PANI content. Blends of 12 and 30 wt. (%) were also obtained following the same procedure using different proportions of aniline, oxidant etc, as described in previous work. PANI content in the blends were calculated on the basis of elemental analysis. Thick films (≈ 200 μm) were obtained by pressing the material (powder form) under a pressure of 30 MPa at 180 ºC. Doped (PANI-HCl) and dedoped (PANI-EB) were obtained using the same procedure in the absence of PVDF.

2.2. Measurements

Thermogravimetric Analysis (TGA) was performed in a Netzch STA 409 equipment within a temperature range of 25 to 700 ºC at a heating rate of 10 ºC/min and N₂ atmosphere. Differential Scanning Calorimetry (DSC) analysis were performed in a TA Instruments MDSC 2920 equipment within a temperature range of 0 to 300 ºC at a heating rate of 10 ºC/min in N₂ atmosphere. The Dynamic Mechanical Analysis (DMA) was performed using a TA Instruments DMA Q800 V7.0 analyzer. The measurements were performed from -80 ºC to 80 ºC at a heating rate of 2 ºC/min under N₂ and a constant frequency of 1.0 Hz. The stress-strain tests were conducted using an EMIC DL 300 equipment at room temperature and a deformation rate of 13 mm/min using a cell of 100 N and initial grips separation of 23.4 mm. The samples were strips cut from a thin sheet following the specifications of the ASTM D882-95a standard. Five specimens were tested for each sample composition.

3. Results and Discussion

Thermogravimetric analysis provides useful information on the thermal stability of materials. Figure 1 shows the thermogravimetric behavior of the PANI, PVDF and the blends investigated in this work. The onset degradation temperature of the polymer chain for pristine PVDF^29,30 is around 400 ºC. On the other hand, redoped PANI (PANI-HCl) presents considerable weight loss at much lower temperatures than for PVDF. The weight loss below 150ºC has been assigned to water loss^31,32, and at a higher temperature (>150 ºC), due to the loss of bonded water and dopant^32-37. Above 420ºC, the weight loss is associated with the degradation of the polymer chain structure, in agreement with the literature^38,39. The analysis shows that the blends in the compositions studied have a stability that is closest to the stability of PVDF, with a intensive weight loss onset at around 400 ºC, which is associated to the weight losses for PVDF and PANI as discussed above. The thermogravimetric analysis for the PVDF/PANI blend (22.4 wt. (%) PANI), dedoped and redoped with HCl 0.05 M and 1.00 M, is shown in Figure 2. A small weight loss is observed at a temperature lower than 120 ºC in the redoped blends, assigned to water loss, which was not noticed for the dedoped blend. The water absorption is higher for the doped polyaniline due to ionic salvation⁴⁰. Moreover, the redoped blends show a more significant weight loss for temperatures between 300 and 450 ºC, than the dedoped one. A similar behavior is observed in the blends containing 12 and 30 wt. (%) of PANI (Figures 3 and 4, respectively). The results show that the loss of dopant in the blends is related to the acid concentration used for doping. This result is in agreement with the literature⁴¹.

Figure 5 shows the DSC thermograms of the dedoped PANI-EB (emeraldine base), PANI redoped with HCl 1.0M (PANI-HCl) and PVDF. The PANI thermograms show a broad endothermic peak at around 110 ºC, assigned to water loss, which is greater to the redoped PANI. This finding is in agreement with the TGA analysis, discussed above. The graphics also show an exothermic transition at around 270 ºC for the PANI-EB, which has been assigned to cross linking³⁶. This transition is noticed in a smaller extension for the PANI-HCl sample. Scherr et al.⁴² suggested the crosslinking reaction results from a coupling of two neighboring -N=Q=N- groups to give two -NH-B-NH- groups thorough a link of the N with its neighboring quinoid ring. Here Q and B represent the quinoid and benzenoid ring, respectively. In the redoped PANI, the amount of quinoid ring is smaller and consequently the exothermic transition is less emphasized. The endothermic peak observed around 175 ºC for PVDF is assigned to the melting of its crystalline regions³⁷. In Figure 6 thermograms of PVDF, PANI-EB, and PVDF/PANI blends with 12, 22.4 and 30 wt. (%) of dedoped PANI are shown. The exothermic peak at ≈ 250ºC associated with crosslinking⁴³ for dedoped blends can be observed, except for the 12 wt. (%) PANI blend. That must be a consequence of the low percentage of PANI in the sample that compromises the observation of such transition. It is also observed that the melting point of PVDF keeps constant, regardless of the blend composition, hence a strong indication that the polymers are not miscible. On the other hand, the intensity of this peak is proportional to the percentage of PVDF in the blend, as expected, since the peak is related to the melting heat. Figure 7 shows the DSC thermograms of the PVDF, PANI-HCl and the PVDF/PANI blends with 12, 22.4, and 30 wt. (%) of PANI redoped with HCl 1.0 M. The results are similar to those discussed above, with the exception that the degradation peaks are less evident than for the dedoped ones.

Storage modulus (E') and loss factor (tan δ = E"/E') as a function of the temperature for the PVDF are shown in Figure 8. The curve of tan δ has a peak at around -40 ºC that was assigned to the glass transition temperature⁴⁴. This is associated with a strong decrease of the storage modulus in that region. The DMA results obtained for the dedoped PVDF/PANI blends with 12, 22.4 and 30 wt. (%) of PANI can be seen in Figure 9. The presence of PANI in the blend did not change the glass transition temperature, indicating that the blend components are immiscible, in agreement with the results obtained by DSC.

Figure 10 shows the stress-strain curves for pure PVDF and for the PVDF/PANI blends containing 12 and 22.4 wt. (%) of dedoped PANI. It is noticed that the elongation at break decreases as the content of PANI in the blend increases. The tensile increases from 40 MPa for pure PVDF, to 50 and 55 MPa, respectively, for blends with 12 and 22.4 wt. (%) of PANI and the Young modulus changed from 1.2 GPa for PVDF to 1.5 GPa for blends with 12 and 22.4 wt. (%) of PANI (values obtained from the slope of the curves in Figure 8 in the elastic region). Additionally, the elastic region also becomes larger with the increase of the PANI percentage in the blend (changing from 2.5 to 4%), although the value of E does not change. This suggests PANI is reinforcing the PVDF matrix, constraining the PVDF chain movements and increasing the tensile strength of the blend to a higher stiffness associated with the PANI backbone. In order to investigate the effect of doping on the mechanical properties of the blends, stress-strain tests were performed for blends with 12 and 22.4 wt. (%) of PANI redoped with 0.05 and 1.0 M HCl. The results obtained are presented in Figures 11 and 12. As a general behavior, the acid dopant renders the PVDF/PANI more brittle, as the acid used for redoping is more concentrated. The elastic component is not significantly affected by the acid concentration (insets of Figures 11 and 12). It is well known that doped PANI becomes more crystalline at higher doping levels^16,45, diminishing the elongation at break when compared with the undoped one.

4. Conclusions

In conclusion, our results of the blend of PVDF/PANI showed better thermal stability than the conductive polymer alone. The melting point of PVDF crystallites and its glass transition is not affected by the PANI component, showing that the polymers are not miscible. The presence of PANI in the blend increases the tensile strength and the Young modulus, when compared to pure PVDF. On the other hand, the blend becomes more brittle, thus increasing the PANI doped level.

Acknowledgements

The authors are grateful for the financial support given by Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES).

Received: June 11, 2010; Revised: October 19, 2010

1. Yang CY, Cao Y, Smith P and Heeger AJ. Morphology of conductive solution-processed blends of polyaniline and poly(methyl methacrylate). Synthetic Metals 1993; 53:293-391.
2. Wang P, Tan KL, Kang ET and Neoh KG. Preparation and characterization of semi-conductive poly(vinylidene fluoride)/polyaniline blends an membranes. Applied Surfarce Science 2002; 193:36-45.
3. Malmonge LF and Mattoso LHC. Electroactive blends of poly(vinylidene fluoride) and polyaniline derivatives. Polymer 1995; 36:245-249.
4. Barra GMO, Matins RR, Kafer KA, Paniago R, Vasques CT and Pires ATN. Thermoplastic elastomer/polyaniline blends: evaluation of mechanical and electromechanical properties. Polymer Testing 2008; 27:886-892.
5. Schettini ARA, Peres RCD and Soares BG. Synthesis of polyaniline/camphor sulfonic acid in formic acid medium and their blends with polyamide-6 by in situ polymerization. Synthetic Metals 2009; 159:1491-1495.
6. Rubinger CPL, Faez R, Costa C, Martins CR and Rubinger RM. Dielectric properties of PANI/PSS blends obtained by in situ polymerization technique. Polymer Bulletin 2008; 60:379-386.
7. Malmonge LF, Lopes GA, Langiano SC, Malmonge JA, Cordeiro JMM and Mattoso LHC. A new route to obtain PVDF/PANI conducting blends. European Polymer Journal 2006; 42:3108-3113.
8. Faez R, Gazotti WA and De Paoli MA. An elastomeric conductor based on polyaniline prepared by mechanical mixing. Polymer 1999; 40:5497-5503.
9. Cruz-Estrada RH and Folkes MJ. In-situ production of electrically conductive fibres in polyaniline-SBS blends. Journal of Materials Science 2000; 35:5065-5069.
10. Ray S, Easteal AJ, Cooney RP and Edmonds NR. Structure and properties of melt-processed PVDF/PMMA/polyaniline blends. Material Chemistry and Physics 2009; 113:829-838.
11. Ruckenstein E and Yang S. An Emulsion pathway to electrically conductive polyaniline-polyestirene composites. Synthetic Metals 2003; 53:283-292.
12. Yang S and Ruckenstein E. Processable conductive composites of polyaniline/poly(alkilmethacrylate) prepared via an emulsion method. Synthetic Metals 1993; 59:1-12.
13. Jeon BH, Kim S, Choi MH and Chung IJ. Synthesis and characterization of polyaniline-carbonate composites prepared by an emulsion polymerization. Synthetic Metals 1999; 104:95-100.
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15. Xie HQ, Ma YM and Guo JS. Conductive polyaniline-SBS Composites from in situ emulsion polymerization. Polymer 1998; 40:261-265.
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24. Benz M and Euler WB. Determination of the Crystalline Phases of Poly(vinylidene fluoride) Under Different Preparation Conditions Using Differential Scanning Calorimetry and Infrared Spectroscopy. Journal of Applied Polymer Science 2003; 89:1093-1100.
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36. Pandey SS, Gerard M, Sharma AL and Malhotra BD. Thermal analysis of chemically synthesized polyemeraldine base. Journal of Appied Polymer Science 2000; 75(1):149-155.
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*

e-mail:

lfmal@dfq.feis.unesp.br

Publication Dates

Publication in this collection
24 Jan 2011
Date of issue
Dec 2010

History

Received
11 June 2010
Reviewed
19 Oct 2010

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Yang CY, Cao Y, Smith P and Heeger AJ. Morphology of conductive solution-processed blends of polyaniline and poly(methyl methacrylate). Synthetic Metals 1993; 53:293-391.

[2] 2. Wang P, Tan KL, Kang ET and Neoh KG. Preparation and characterization of semi-conductive poly(vinylidene fluoride)/polyaniline blends an membranes. Applied Surfarce Science 2002; 193:36-45.

[3] 3. Malmonge LF and Mattoso LHC. Electroactive blends of poly(vinylidene fluoride) and polyaniline derivatives. Polymer 1995; 36:245-249.

[4] 4. Barra GMO, Matins RR, Kafer KA, Paniago R, Vasques CT and Pires ATN. Thermoplastic elastomer/polyaniline blends: evaluation of mechanical and electromechanical properties. Polymer Testing 2008; 27:886-892.

[5] 5. Schettini ARA, Peres RCD and Soares BG. Synthesis of polyaniline/camphor sulfonic acid in formic acid medium and their blends with polyamide-6 by in situ polymerization. Synthetic Metals 2009; 159:1491-1495.

[6] 6. Rubinger CPL, Faez R, Costa C, Martins CR and Rubinger RM. Dielectric properties of PANI/PSS blends obtained by in situ polymerization technique. Polymer Bulletin 2008; 60:379-386.

[7] 7. Malmonge LF, Lopes GA, Langiano SC, Malmonge JA, Cordeiro JMM and Mattoso LHC. A new route to obtain PVDF/PANI conducting blends. European Polymer Journal 2006; 42:3108-3113.

[8] 8. Faez R, Gazotti WA and De Paoli MA. An elastomeric conductor based on polyaniline prepared by mechanical mixing. Polymer 1999; 40:5497-5503.

[9] 9. Cruz-Estrada RH and Folkes MJ. In-situ production of electrically conductive fibres in polyaniline-SBS blends. Journal of Materials Science 2000; 35:5065-5069.

[10] 10. Ray S, Easteal AJ, Cooney RP and Edmonds NR. Structure and properties of melt-processed PVDF/PMMA/polyaniline blends. Material Chemistry and Physics 2009; 113:829-838.

[11] 11. Ruckenstein E and Yang S. An Emulsion pathway to electrically conductive polyaniline-polyestirene composites. Synthetic Metals 2003; 53:283-292.

[12] 12. Yang S and Ruckenstein E. Processable conductive composites of polyaniline/poly(alkilmethacrylate) prepared via an emulsion method. Synthetic Metals 1993; 59:1-12.

[13] 13. Jeon BH, Kim S, Choi MH and Chung IJ. Synthesis and characterization of polyaniline-carbonate composites prepared by an emulsion polymerization. Synthetic Metals 1999; 104:95-100.

[14] 14. Rao PS, Subrahmanya S and Sathyanarayana DN. Polyaniline-polycarbonate blends synthesized by two emulsion pathway. Synthetic Metals 2004; 143:323-330.

[15] 15. Xie HQ, Ma YM and Guo JS. Conductive polyaniline-SBS Composites from in situ emulsion polymerization. Polymer 1998; 40:261-265.

[16] 16. Ruckenstein E and Sun Y. Polyaniline-containing electrical conductive composite prepared by two inverted emulsion pathways. Synthetic Metals 1995; 74:107-113.

[17] 17. Rao PS, Subrahmanya S and Sathyanarayana DN. Inverse emulsion polymerization: a new route for the synthesis of conducting polyaniline. Synthetic Metals 2002; 128:311-316.

[18] 18. Rao PS and Sathyanarayana DN. Inverted emulsion cast electrically conducting polyaniline-polystyrene blends. Applied of Polymer Science. 2002; 86:1163-1171.

[19] 19. Rao PS, Subrahmanya S and Sathyanarayana DN. Synthesis by inverse emulsion pathway and characterization of polyaniline-poly(ethylene-co-vinyl acetate) blends. Synthetic Metals 2003; 139:397-404.

[20] 20. Su H, Strachan A and Goddard WA. Density functional theory and molecular dynamics studies of the energetics and kinetics of electroactive polymers: PVDF and P(VDF-TrFE). Physical Review B. 2004; 70(6):64101.

[21] 21. Nakhmanson SM, Nardelli MB and Bernholc J. Ab Initio Studies of Polarization and Piezoelectricity in Vinylidene Fluoride and BN-Based Polymers. Physical Review Letter 2004; 92(11):115504.

[22] 22. Yee WA, Kotaki M, Liu Y and Lu XH. Morphology, polymorphism behavior and molecular orientation of electrospun poly(vinylidene fluoride) fibers. Polymer. 2007; 48:512-521.

[23] 23. Gao Q and Scheinbein JI. Dipolar Intermolecular Interactions, Structural Development, and Electromechanical Properties in Ferroelectric Polymer Blends of Nylon-11 and Poly(vinylidene fluoride). Macromolecules 2000; 33:7564-7572.

[24] 24. Benz M and Euler WB. Determination of the Crystalline Phases of Poly(vinylidene fluoride) Under Different Preparation Conditions Using Differential Scanning Calorimetry and Infrared Spectroscopy. Journal of Applied Polymer Science 2003; 89:1093-1100.

[25] 25. Ramer NJ, Marrone T and Stiso KA. Structure and vibrational frequency determination for a-poly(vinylidene fluoride) using density-functional theory. Polymer 2006; 47:7160-7165.

[26] 26. Mohammadi B, Yousefi AA and Bellah SM. Effect of tensile strain rate and elongation on crystalline structure and piezoelectric properties of PVDF thin films. Polymer Testing. 2007; 26:42-50.

[27] 27. Huang C and Zhang QM. Fully functionalized high-dielectric-constant nanophase polymers with high electromechanical response. Advanced Materials 2005; 17:1153-1158.

[28] 28. Bobnar V, Levistk A, Huang C and Zhang QM. Enhanced dielectric response in all-organic polyaniline - poly(vinylidene fluoride-trifluoroethylenechlorotrifluoroethylene) composite. Journal of Non-Crystalline Solids 2007; 353:205-209.

[29] 29. Lovinger AJ. Poly(vinylidene fluoride) In: Basset DC, editor. Development in Crystalline Polymers London: Applied Science Publisher; 1982.

[30] 30. Zulfiqar S, Zulfiqar M and Munir A. Study of the thermal-degradation of polychlorotrifluoroethylene, poly(vinylidene fluoride) and copolymers of chlorotrifluoroethylene and vinylidene fluoride. Polymer Degradation and Stability 1994; 43(3):423-430.

[31] 31. Lei X, Guo X, Zhang L, Wang Y and Su ZJ. Synthesis and properties of novel conducting polyaniline copolymers. Applied of Polymer Science 2007; 103(1):140-147.

[32] 32. Sinha M, Bhadra S and Khastgir D. Effect of Dopant Type on the Properties of Polyaniline. Journal of Applied Polymer Science 2009; 112:3135-3140.

[33] 33. Morgan H, Foot PJS and Brooks NW. Thes effects of composition and processing variables on the properties of thermoplastic polyaniline blends and composites. Journal of Materials Science 2001; 36:5369-5377.

[34] 34. Palaniappan S and Narayana BH. Conducting polyaniline salts-thermogravimetric and differential thermal analysis. Thermochimica Acta 1994; 237(1):91-97.

[35] 35. Palaniappan S and Narayana BH. Temperature effect on conducting polyaniline salts-thermal and spectral studies. Journal of Polymer Science Part A-Polymer Chemistry 1994; 32(13):2431-2436.

[36] 36. Pandey SS, Gerard M, Sharma AL and Malhotra BD. Thermal analysis of chemically synthesized polyemeraldine base. Journal of Appied Polymer Science 2000; 75(1):149-155.

[37] 37. Malmonge LF and Mattoso LHC. Thermal analysis of conductive blends of PVDF and poly(o-methoxyaniline). Polymer 2000; 41:8387-8391.

[38] 38. Conklin JA, Huang SC, Huang SM, Wen T and Kaner RB. Thermal Properties of Polyaniline and Poly( aniline-co-o-ethylaniline). Macromolecules 1995; 28:6522-6527.

[39] 39. Li W and Wan M. Stability of Polyaniline Synthesized by a Doping-Dedoping-Redoping Method. Journal of Applied Polymer Science. 1999; 71:615-621.

[40] 40. Ostwal MM, Sahimi M and Tsotsis TT. Water harvesting using a conducting polymer: A study by molecular dynamics simulation. Physical Review E 2009; 79:061801(1-16).

[41] 41. Ostwal MM, Pellegrino J, Norris I, Tsotsis TT, Sahimi M and Mattes BR. Water Sorption of Acid-Doped Polyaniline Solid Fibers: Equilibrium and Kinetic Response. Industrial of Engineering Chemistry Research 2005; 4:7860-7867.

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Thermal and mechanical properties of PVDF/PANI blends

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