Synthesis and characterization of pani ti o2 nanocomposite for solar
- 1. Synthesis and characterization of PANI-TiO2 nanocomposite for solar cell application SHASHI KUMAR M.Sc. (Applied Physics) (15MS000278) Department of Applied Physics IIT(ISM), Dhanbad Under the supervision of DR. R.B. CHOUDHARY ASSISTANT PROFESSOR Department of Applied physics Indian Institute of Technology (Indian School of Mines), Dhanbad 09-May-17 1
- 2. Outline Introduction Preparation of PANI-TiO2 nanocomposite Characterization Techniques and it’s Results X-ray Diffraction Fourier Transform Infrared spectroscopy (FT-IR) Field Emission Scanning Electron Microscope (FESEM) I-V Characteristics Conclusion Applications 09-May-17 2
- 3. Introduction to Polymers Long chain like molecular structure where repeated molecular units (Monomer) are connected by covalent bond. polymers were considered as insulaters and were used as insulating materials example like Polyethylene. But according to Shirakawa polymers can be conducting so Conducting polymers are those polymers which Conduct electricity due to delocalization of π electrons. E.g- Polyacetylene, Polythiophene, Polyaniline ,Polypyrrole etc. 09-May-17 3
- 4. Polymer becomes electronically charged Polymer chains generate charge carriers Polyaniline (PANI) is a conducting polymer of the semi-flexible rod polymer family. First discovered in the 19th century by Henry Lethe . It is also known as Aniline Black. PANI is one of the most attractive conducting polymers due to the high conductivity and good stability. 09-May-17 4
- 5. 09-May-17 5 TiO2has also been studied to prepare its composite with conducting polymers The introduction of TiO2 nanoparticles to PANI because TiO2 absorb UV light energy can enhance the ability, compatibility dispersability and durability of polymer . Chemical formula TiO2 Molar Mass 79.866 g/mol Density 4.23 g/cm3 (Rutile) 3.78 g/cm3 (Anatase) Melting Point 1,843 °C (3,349 °F; 2,116 K) Boiling point 2,972 °C (5,382 °F; 3,245 K) Solubility in water Insoluble Band Gap 3.05 eV (rutile) Properties of TiO2
- 6. Preparation of TiO2 and PANI-TiO2 nanocomposite Preparation of TiO2 nanoparticles stirring stirring washing Filtering - Drying 09-May-17 6 Ticl4 H2 O Ticl4 Solution Mixed Solution (NH4)2SO4 + HCL precipitate TiO2 powder 20 oC – 95 oC NH4OH
- 7. Preparation of PANI-TiO2 nanocomposite 09-May-17 7
- 8. Characterization Techniques and it’s Results XRD Analysis:- XRD Figure (a, b, c, d, e, f) corresponds to pure aniline (C6H5NH2), TiO2, and PANI-TiO2 (2%, 4%, 6%, and 8%). 09-May-17 8
- 9. Figure (a) show that the XRD pattern of PANI has broad band at a value of 2θ ≈25.54 degree and TiO2 has a sharp peak of maximum intensity at 25.3 degree along with certain other peaks of low intensity. The average crystallite size of PANI and PANI-TiO2 composites has been calculated using Scherrer’s formula. When applied for the characteristics (101 planes) peak of TiO2 and its composite with PANI leads to an average size of about 35nm. 09-May-17 9
- 10. (FT-IR) Analysis 09-May-17 10 FTIR spectra pure PANI and PANI-TiO2 (2%, 4%, 6%, and 8%) nanocomposites have been shown in figure.
- 11. The detailed FTIR peak assignments for pure PANI and PANI-TiO2 nanocomposites have been shown in Table. 09-May-17 11 FTIR peak assignments Pure PANI(cm-1) PANI-2%TiO2(cm-1) PANI-4%TiO2(cm-1) PANI-6%TiO2(cm-1) C-H bending vibration 797 797 797 797 C-H benzenoid ring vibration 1123 1123 1123 1123 C-C stretching vibration 1401 1304 1301 1307 C =C stretching vibration 1460 1473 1476 1465 C=N stretching vibration 1569 1569 1561 1575 C- N stretching vibration 1296 1295 1295 1295
- 12. The broad band of O-Ti-O network assigned at 804– 500 cm-1 . The peaks at 1563 and1460 cm-1 showed stretching mode of C=N and C=C vibration for quinoid ring and benzenoid units. The peak at 797 cm-1 was attributed to C-H vibration for benzenoid ring. In case of composite of PANI-TiO2 there exists a small shifting in frequencies of PANI band. In PANI-TiO2 composites the bands of TiO2 are also visible . The FTIR confirms the presence of TiO2 in composite 09-May-17 12
- 14. The morphological properties of pure PANI, titanium oxide (TiO2), and PANI-TiO2 (2%, 4%, 6%, and 8%) nanocomposites were examined using FESEM technique. Figure (a) showed morphology of pure PANI with uniform nanofiber structure. Figure (b) shows that the surface of TiO2 nanoparticles was arranged in highly irregular fashion with varying diameter. Figure (c, d, e, f) shows morphology of nanocomposite. Figure(d) shows the existence of both fibrous as well as nanoparticle structures confirming the formation of nanocomposite. With increase in concentration of Tio2 uniform coating of nanopraticles is observed on fibrous polymer matrix. 09-May-17 14
- 15. I-V Characteristics 09-May-17 15 I-V Characteristics PANI,PANI-2%TiO2 (t2), PANI-4%TiO2 (t4), PANI-6%TiO2 (t6), PANI- 2%TiO2 (t8).
- 16. The electrical properties of PANI and PANI- TiO2 nanocomposite were analyzed by performing Current to Voltage characterization It can be observed from the I-V curve that current intensity was increased from 6.8 μA to 75.5 μA (at +10 V) as the TiO2 concentration increased to 2% and 6% respectively; compared to pure one Further increase in TiO2 concentration leads to decrease in current. Hence, for PANI-6% TiO2 maximum current was observed. 09-May-17 16
- 17. Conclusion The XRD pattern confirms the formation of TiO2which was validated by JCPDS-00-010-0063. The FTIR confirms the presence of TiO2 in composite of PANI- TiO2 .there exists small shifting of frequency band in PANI . The FESEM study of PANI-TiO2 shows uniform distribution of TiO2 in the PANI matrix. Current- Voltage Characteristics shows that as current intensity increases as TiO2 concentration increased compared to pure one. Further increase in TiO2 concentration leads to decrease in current 09-May-17 17
- 18. Applications Conducting polymers have many uses. Solar cells Light Emitting Diodes (LEDs) Transistor Sensor Battery.etc 09-May-17 18
- 19. References A.K. Bakshi, Scientific reporter, March 1989, p.141. M. Majhi, R.B. Choudhary, and P. Maji, Bull. Mater. Sci., 38, 1195 (2015). www.thermonicolet.com/P/N 169-707500 2/01 S. Maiti, J. of Sci. and Industrial research, 48, December 1989, p.581. H. Letheby, On the production of a blue substance by the electrolysis of sulphate of aniline, J. Chem. Soc., vol. 15, pp. 161-163, 1862. N. Gandhi, K. Singh, A. Ohlan, D.P. Singh, and S.K. Dhawan, Compos. Sci. Technol., 71, 1754 (2011). 09-May-17 19