Research Journal of Chemical Sciences ______________________________________________ ISSN 2231-606X Vol. 5(6), 59-63, June (2015)                      Res. J. Chem. Sci. International Science Congress Association     
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Frequency and Temperature dependence studies in PTh-V5 composites Jyoti Kattimani, T. Sankarappa*, R. Ramanna and J. S. Ashwajeet Department of Physics, Gulbarga University, Gulbarga-585106, Karnataka, INDIAAvailable online at: www.isca.in, www.isca.me Received 5th June 2015, revised 10th June 2015, accepted 17th June 2015 AbstractBy oxidation method, Polythiophene (PTh) has been prepared. Composites were prepared by mixing Polythiophene and Vin different weight percentages. Their phases were confirmed by XRD and SEM studies. Dielectric properties and AC conductivity were measured over broad range of frequency and temperature. Conductivity varied with temperature is the semiconductor fashion. Dielectric constant and loss both were found to decrease with increase in frequency and increased with increase in temperature. Conductivity variation with temperature has been analysed in terms of small polaron hopping theory of Mott. Keywords: Polythiophene, nanocomposites, conductivity, polaron hopping, activation energy. Introduction The conducting polymers have been of great importance as this exhibit unique optical, electrical, chemical and thermal properties. Among these polymers, polythiohene (PTh) received, attention due to its high conductivity and thermal stability1-4. The conductivity of these materials can be tuned by doping. Dopant anion palys important role in polymerization5,6. Polymer nanocomposites are considered to be hybrid. Nano composites of polymers are used in drug delivery, conductive paints, betteries etc7-13. Vanadium oxides are polyfunctional materials and shows metal semiconductor transition. V is used an active electrode in a rechargeable lithium battery, elctro chromic devices, catalysts etc14-19. The conductivity of PTh-Zno composites were measured and found it to be order of 10-4/m. The room temperature conductivity of polypyrrole-TeOand PTh-TeO composites have been reported to be 1 x 10-5cm-1 and 2 x 10-2cm-1 respectively20. In these composites, conductivity have been observed to have increased by 10 to 10orders of magnitude compared to their pure PPy and PTh. PPy- composites of different wt% in the range from 10 to 50 wt% were prepared by chemical oxidative method. The room temperature conductivity of these composites at 100 KHz revealed that the addition of vanadium oxide nanoparticle results in the decrease in conductivity up to 10% V and remain constant for higher amount of V. The ac conductivity of pure PPy increased with frequency and PPy-V2O5 composite showed constant up to the frequency of 10 Hz and then increased steeply16. Polyaniline-V composites showed constant conductivity up to 10 Hz17, 18.  DC conductivity of polyaniline-V composites of different wt% of V was found to change from 10-7 to 10-9cm-1, attaining a maximum value for 30 of V15. Here, we present the result of dielectric results for PTh-V nanocomposites. AC conductivity has been determined using dielectric data. Frequency and temperature dependence of both dielectric data and conductivity data has been thoroughly analyzed. Material and Methods PTh was prepared at 323K using AR grade Thiophene, Ferric chloride, Methanol and Chloroform. Homogenous aqueous solution of thiophene was prepared. Chloroform and ferric chloride solutions were mixed drop by drop to the PTh solution. The mixture magnetically stirred for 24 hours and filtered. The precipitate so formed was washed with chloroform and then with methanol. In this process, the precipitate changed its colour to brown indicating the formation of Polythiophene .The powder was dried up and subsequently grinded20,21. The PTh- composites were prepared by mixing Polythiophene and analytical grade V in different wt% defined as (PTh) 100-x (V)x, where x= 5%, 10% and 15% labelled as PTh-VO1, PTh-VO2 and PTh-VO3 respectively. Powders were subjected to XRD and SEM studies. From these studies, it is confirmed that the grains in these composites are of nano size22. Powders of the composites were pressed into pellets. Capacitance, C, and dissipation factor, tan, were measured as function of frequency and temperature in the range from 50Hz to 3MHz and 300K to 423K respectively. These measurements were carried out in a precession impedence analyser (Wayne Kerr make Model No. 6500B). Temperature was sensed using Chromel-Alumel thermo- couple with the accuracy of ± 1K.  Results and Discussion Dielectric properties: Using the measured capacitance and dissipation factor the dielectric parameters were determined for all the composites, using the expressions given in reference23.  Figure-1 shows the variation of dielectric constant, ' with frequency for all the three composites. From this figure, we note that, ' decrease gradually with frequency upto 70 KHz and become constant for higher frequencies. Dielectric loss factor, " variation with frequency for all the three composites is 
Research Journal of Chemical Sciences ___________________________________________________________ ISSN 2231-606XVol. 5(6), 59-63, June (2015) Res. J. Chem. Sci.  International Science Congress Association            
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plotted in figure-2. " varied with frequency in the same fashion as that of '. Temperature variation of ' for PTh-VO1 is shown in figure-3. In this figure, we see that ' increases with temperature. Similar nature of variation of ' with temperature has been observed for the remaining composites. The change in " with temperature for PTh-VO1 is shown in figure-4. Similar behaviour of " with temperature has been observed for the remaining composites. 468101214161x102x103x104x105x10
ln(f) (Hz)
 PTh-VO1
 PTh-VO2
 PTh-VO3Figure-1 Dielectric constant, ' versus ln(f) for PTh-VO nanocomposites at the temperature of 323K 468101214160.004.50x109.00x101.35x101.80x10
ln(f) (Hz)
 PTh-VO1
 PTh-VO2
 PTh-VO3Figure-2 Dielectric loss, " versus ln(f) for  PTh-VO nanocomposites at the temperature  of323KElectrical Conductivity: Conductivity, , has been determined using dielectric data using the following equation 24. ac = " (1) Where:  is free space permittivity which is equal to 8.85 x 1012 Fm-1. Conductivity variation with temperature for different frequencies for the composite PTh-VO2 is shown in figure-5. 468101214161.5x102.0x102.5x103.0x103.5x104.0x10
ln(f) (Hz)
 323K
 343K
 363K
 383K
 403K
 423KFigure-3 Dielectric constant, ' versus ln(f) for PTh-VO1 nanocomposites for different Temperatures468101214161x102x103x104x105x106x10
eee"
ln(f) (Hz)
 323K
 343K
 363K
 383K
 403K
 423KFigure-4 Dielectric loss, " versus ln(f) for PTh-VO1 nanocomposites for different temperaturesIt can be seen in figure-5 that conductivity increases with increasing temperature indicating semiconducting type of behaviour. It also increased with increasing frequency. Similar results have been reported for polyaniline doped with silver nanoparticles, polyaniline doped with cobalt and polyaniline doped with nickel oxide25-27. All the present composites behaved in the same way. Variation of conductivity of all the present composites was found to be within the same order of magnitude i.e, 10-4 (-1-1).   Conductivity variation with V content for two different frequencies at temperature of 403K is shown in figure-6. From figure-6 it is clear that conductivity decreased with increasing  content.  The conductivity data as a function of temperature has been fit 
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to the Mott Small Polaron Hopping (SPH) theory. This theory gave the conductivity expression as28, 
exp (2) Where E the activation energy for small polaron hopping. The plots of ln(T) versus (1/T) were made as per eqnuation-2 for the composite PTh-VO2 and shown in figure-7. The linear lines were fit to the data in the high temperature region where the data appeared linear. Activation energy, E for ac conductivity was calculated using the slopes of the fit linear lines. Activation energy, E versus V content determined for the present composites for different frequencies are plotted in figure-8. 320340360380400420
440
0.001.50x10-43.00x10-44.50x10-46.00x10-47.50x10-4
 (-1-1
T (K)
 500 Hz
 10 K Hz
 100 K Hz
 1 M HzFigure-5 Temperature dependence of electrical conductivity of PTh-VO2 composite nanoparticles at different frequencies510151.0x10-42.0x10-43.0x10-44.0x10-45.0x10-46.0x10-47.0x10-4
  (-1-1 wt.%
 10K Hz
 1M HzFigure-6 Conductivity versus wt % of V in  PTh-VO nanocomposites for two different frequencies at T=403K2.32.42.52.62.72.82.93.03.13.2-7-6-5-4-3-2-1
ln (T) (-1-1K)(1/T) x 1000 (K-1
 500Hz
 10 K Hz
 100 K Hz
 1M HzFigure-7 Plots of ln(T) versus (1/T) for PTh-VO2 composite for four different frequencies. Solid lines are linear fits as per Mott’s SPH model510150.200.250.300.350.400.450.50
 (meV) wt.%
 10K Hz
 1M HzFigure-8 Activation energy versus wt. % of V for PTh-VO nanocomposites at two different frequencies From the figure-8 one can note that Ea increases with increase of  content and decreased with increase of frequency. Increase in E with increase in V concentration may be that addition of V content to the PTh network contributes more to the scattering of polarons. Similar results have been reported for polyaniline doped with V, polyanilinedoped with CeO and polypyrrole doped with Ag17,29,30. Conclusion Polythophene has been synthesised at 323K by chemical method. PTh-V composites were prepared by mixing Polythiophene and V in different weight percentages. The changes in dielectric properties with temperature and frequency were measured over broad ranges. Dielectric constant decreased with increase in frequency and increased with temperature. Dielectric loss decreased with increase in frequency and 
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increased with temperature. Conductivity increased with increase of both temperature and frequency. By employing Mott’s Small Polaron Hopping Model’s conductivity expression, activation energy for ac conductivity has been obtained. Activation energy was found to be decreased with increase in frequency and increased with V content and it may be attributed to increase in the scattering rate of polarons with increase in V5 content. References1.Tiwari D.C, Vikas Sen and Rishi Sharma, Temperature dependent studies of electrical and dielectric properties of Polythiophene based nano composite, Indian Journal of Pure and Applied Physics,50, 49-56 (2012) 2.Rashmi Saxena, Vinodini Shaktawat, Kananbala Sharma, Narendra S Saxena and Thaneshwar Sharma P., Measurement of Thermal Transport Properties in Metal Doped Polypyrrole, Iranian Polymer Journal,17(9), 659-668 (2008) 3.Guanghao Lu, Haowei Tang, Yunpeng Qu, Ligui Li and Xiaoniu Yang., Enhanced Electrical Conductivity of Highly Crystalline Polythiophene/Insulating-Polymer Composite, Macromolecules,40, 6579-6584 (2007)4.Mohd. Hanief  Najar and Kowsar Majid, Synthesis, Characterization, electrical and thermal properties of nanocomposite of  Polythiophene with nanophotoadduct: A potent composite for electronic use, J Mater Sci: Mater Electron, DOI 10. 1007/s 10854-013-1407-8 (2013) 5.Kamat S.V, Tamboli S.H, Vijaya puri, Puri R.K., Yadav J.B. and Oh Shom Joo, Post deposition heating effects on the properties of  Polythiophene thin films, Archives of physics research,1(4) 119-125 (2010) 6.Kamat S.V, Tamboli S.H, Vijaya puri, Yadav J.B. andOh Shom Joo, Optical and electrical properties of Polythiophene thin films: Effect of post deposition heating, Journal of optoelectronics and advanced materials,12(11), 2301-2305 (2010)7.Tabassum Akhtar and Masood Alam, Synthesis, Characterization and Electrical Conductivity of Zinc Oxide Nanoparticles Embedded in Polythophene Nanocomposites, Science of Advanced Materials,, 1–8 (2014)8.Anish Khan, Abdullah M. Asiri, Aftab Aslam Parwaz Khan and Sher Bahadar Khan, Arabian, Electrical conductivity and ion-exchange kinetic studies of Polythiophene Sn(VI) phosphate nano composite cation-exchanger, Journal of Chemistry, doi.org/10.1016/j. Arabje, (2014)9.Rita Sulub S, Martinez-Millan W and Mascha Smit A, Study of the Catalytic Activity for Oxygen Reduction of Polythiophene Modified with Cobalt or Nickel, Int. J. Electrochem. Sci.,, 1015-1027 (2009)10.Posudievskii O. Yu, Kurys Ya I., Biskulova S.A., Malinovskii Yu. K. and Pokhodenko V.D., Nanocomposites produced by direct intercalation of secondary doped polyaniline in V2O5, Theoretical and Experimental Chemistry,38, 278-282 (2002)11.Bharati Nandapure, Subhash Kondawar, Mahesh Salunkhe and Arti Nandapure, Nanostructure cobalt oxide reinforced conductive and magnetic polyaniline nanocomposites, Journal of Composite Materials,47(5), 559-567 (2012)12.Maryam Aghazadeh and Fatemeh Aghazadeh, Electrical conductivity property study of polyaniline-cobalt nanocomposite, Journal of Applied Chemical Research,7(3)47-55 (2013)13.Nanadapure B.I., Kondawar S.B. and Nandapure A.I., Magnetic properties of nanostructured cobalt and nickel oxide reinforced polyaniline composites, International Journal of Computer Application,(2012)14.Shevchuk V.N, Usatenko Yu.N, Demchenko P.Yu, Antonyak  T.O. and Serkiz R.Ya.,  Nano and microsize  structures, Chem. Met. Alloys,67-71 (2011)15.Shama Islam G.B., Lakshmi V.S, Azher M. Siddiqui, Husain M and Zulfequar,  Synthesis, electrical conductivity and dielectric behaviour of polyaniline/Vcomposites, International Journal of Polymer Science,doi.org/10.1155, 307525 (2013)16.Nurhizwati Abd. Rahman, Tunku Ishak Tunku Kudin, Ab. Malik Marwan Ali and Muhd Zu Azhan Yahya, Synthesis and characterization of composite polypyrrole-vanadium oxide (PPy/V), Journal of Materials Science and Engineering B, , 457-460 (2011)17.Parinitha M. and Venkateshlu A., Dielectric and AC conductivity studies of vanadium pentaoxide doped polyaniline composites, International Journal of Engineering and Science,2(2), 45-50 (2013)18.Vijaykumar B, Chanshetty Sharanappa G, Patil B.M. and Sangshetty K., Transport properties of polyaniline-composites, International Journal of Engineering Research,, 105-122 (2013)19.Shama Islam, Mohsin Ganaie, Shabir Ahmad, Azher M. Siddiqui and Zulfequar M.,  Dopant effect and characterization of poly (O-Toluidine)/ vanadium pentoxide composites prepared by in situ polymerization process, International Journal of Physics and Astronomy,, 105-122 (2014)20.Kowsar Majid, Tabassum R, Shah A.F., Ahmad S. and Singla M.L., Comparative study of synthesis, characterization and electrical properties of polypyrrole and Polythiophene composites with tellurium oxide, J Mter Sci: Mater Electron, 20, 958-966 (2009)
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21.Jyoti Kattimani, Sankarappa T, Praveenkumar K, Ashwajeet J.S., Ramanna R, Chandraprabha G.B. and Sujatha T., Structure and temperature dependence of electrical conductivity in Polythiophene nanoparticles, International Journal of Advanced Research in Physical Science,, 17-21 (2014)22.Jyoti Kattimani T., Sankarappa  J. S., Ashwajeet R., Ramanna K., Praveenkumar and Chandraprabha G, DC Conduction in Polythiophene Nanocomposites doped with V5, (communicated to a journal), (2015)23.Ashwajeet J. S, Sankarappa T, Ramanna R. and Praveen Kumar K., Dielectrical studies in Li2O and CoO doped borophosphate glasses, Journal of Advances in Physics,8(3), 2256-2266 (2015) 24.Sujatha T, Devidas G.B., Sankarappa T and Hanagodimath S.M., Dielectric and AC conductivity studies in alkali doped vanadophosphate glasses, International Journal of Engineering Sciences,2(7) 302-309 (2013)25.Safenaz M. Reda, Sheikha M. and Al-Ghannam., Synthesis and electrical properties of polyaniline composite with silver nanoparticles, Advances in Materials Physics and Chemistry,, 75-81 (2012)26.Ghosh P., Sarkar A, Meikap A.K, Chattopadhyay S.K, Chatterjee S.K. and Ghosh M., Electron transport properties of cobalt doped polyaniline, Journal of Physics D: Applied Physics,39, 3047-3052 (2006)27.Sneh Lata Goyal, Smriti Sharma, Deepika Jain, Kumar D and Kishore N., In situ synthesis and characterization of polyaniline/ nickel oxide composites, Advances in Applied Sciece Research,6(1), 89-98 (2015) 28.Mott N.F., Conduction in glasses containing transition metal ions, J. Non-Cryst. Solids, 1(1)1-17 (1968)29.Sangshetty Kalyane, AC conductivity study of polyaniline-CeO composites, International Journal of Scientific Research,, 332-333 (2013)30.Praveenkumar K, Sankarappa T, Jyoti Kattimani, Chandraprabha G, Ashwajeet J.S and  Ramanna R,  Electronic transport in PPy-Ag composite nanoparticles, nd International Conference on Nanotechnology, ISBN: 978-81-927756-2-3, 695-699 (2015)
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