Öz
Kaynakça
- [1] Angham, G.H., Farhan, L., Ahmed, H., Hussein, H., Abbas, I.O., Al-Zuheiry Saba, R.S., (2013). Hind. A. Univ. J. Mater. Sci. 1:52-55. [2] Sarychev, K., Bergman, D.J., and Yagil, Y., (1995). Theory of The Optical and Microwave Properties of Metal-Dielectric Films. Physical Review B. 51:5366–5385. [3] Helmuth, H.J., (2009). Quant. Spectrodc. Ra. 110:787–799. [4] Yoochan, H., Yong, M.H., Dae, S.Y., and Jaemoon, Y.J., (1012). Nanobiosensors Based on Localized Surface Plasmon Resonance for Biomarker Detection. Journals of Nanomater. 1-13, ID:759830. [5] Link, S., and El-Sayed, M.A.J., (1999). Physical Chem B 1999, 103, 8410–8426. [6] Prasad, A.K., Kubinski, D.J., and Gouma, P.I., (2003). Sensor. Actuator. B. 93:25–30. [7] Granqvist, C.G., (1995). Handbook of Inorganic Electrochromic Materials, 1st ed. Elsevier, Amsterdam, The Netherlands. [8] Hinokuma, K., Kishimoto, A., and Kudo, T.J., (1994). Electrochem. Soc. 141:876–879. [9] Scarminio, J. and Lourenc, A., (1997). Gorenstein, A. Thin. Solid. Films. 302:66–70. [10] Gretener, C., Perrenoud, J., Kranz, L., Baechler, C., Yoon, S., Romanyuk, Y.E., Buecheler, S., and Tiwari, A.N., (2013). Thin. Solid. Films. 535:193–197. [11] Tarsame, S.S. and Reddy, G.B.J., (2005). Appl. Phys. 98:1-9, ID:026104. [12] Patil, R.S., Uplane, M.D., and Patil, P.S., (2006). Structural and Optical Properties of Electrodeposited Molybdenum Oxide Thin Films, Appl. Surf. Sci. 252:8050–8056, Elsivier. [13] Itoh, T., Matsubara, I., Shin, W., Izu, N., and Nishibori, M., (2008). Preparation of Layered Organic–Inorganic Nanohybrid Thin Films of Molybdenum Trioxide with Polyaniline Derivatives for Aldehyde Gases Sensors of Several Tens PPB Level, Sensor and Actuators B:Chemical, 128:512–520, Elsivier. [14] Seham, H.S., Esraa, A.A., Enas Y.A., and Shaimaa, A.A., (2016). Effect of Gamma Irradiation on The Optical Properties of (PVA: CuCl2) Films, Iraqi Academic Scientific Journals, 57:1968-1974. [15] Omed, G.A., Bakhtyar, K.A., and Sarkawt, A.H.J., (2013). Chem. Mater. Res. 3:84-90, Elsivier. [16] Elimat, Z.M., Zihlif, A.M., and Ragosta, G., (2010). Physica B. 405:3756-3760, Elsivier. [17] Moret, M.P., Devillers, M.A.C., Worhoff, K., and Larsen, P.K.J., (2002). Appl. Phys. 92:468-47, Elsivier. [18] Wemple, S.H. and DiDomenico. M., (1971). Phys. Rev. B3, 1338-1351, Elsivier. [19] Omed, G.A., Yahya, A.K.S., and Salwan, A.S., (2015). Phys. Mater. Chem. 3:18-24, Elsivier. [20] Wasan, A.A., Mohammed, T.A., and Tagreed, K.A., (2011). The MR affect on Optical Properties for Poly (Vinyl alcohol) Films. Baghdad Science Journal, 8:543-550. [21] Shehap, A.M. and Dana, S.A., (2016). Int. J. Nanoelectronics and Materials. 9:17-36. [22] Ghaleb, A.W.A., Hussein, N.N., Ahmed, B., Rafia, T., (2012). Brit. J. Sci. 4:117-124. [23] Mansour, A.F., Mansour, S.F., and Abdo, M.A.J., (2015). Improvement Structural and Optical Properties of ZnO/PVA Nanocomposites, Jounal of Applied Physics, 7:60-69. [24] Omed, G.A., Dlear, R.S., Sherzad, A.T., (2015). The Optical Characterization of Polyvinyl Alcohol: Cobalt Nitrate Solid Polymer Electrolzte Films. Advenced Materials Letters. 6:153-157. [25] Alias, A.N., Zabidi, Z.M., Ali, A.M.M., Harun, M.K., and Yahya, M.Z.A., (2013). Int. J. Appl. Sci. Techn. 3:11-38, Wiley.
Öz
Polyvinyl
alcohol-molybdenum oxide (PVA-MoO3) composite films were prepared by
solution casting technique. The weight percentages of the oxide in the films
were 2.5% and 5%. The films were characterized by using a computerized double
beam UV-VIS spectrophotometer. Optical parameters of the composite films such
as real (n) and imaginary (k) parts of refractive index, optical conductivity
and dielectric constant were calculated. Other optical parameters (the
oscillator energy (E0) and dispersion energy (Ed)) have
been also evaluated. The obtained results revealed that doping of MoO3
had a significant effect on the optical properties. The results showed that the increased ratio
of the oxide led to an increase in the calculated values of the PVA film
parameters and shifted toward high wavelength. The addition of 5.0% of MoO3
to PVA film raised the refractive index (n) value by 38.5%. The Results of this
study show that the PVA-MoO3 film can have many applications,
especially in the area of antireflective coating and photonic devices.
Anahtar Kelimeler
Nanocomposite Optical Parameters Polyvinyl Alcohol Molybdenum Oxide Refractive Index
Kaynakça
- [1] Angham, G.H., Farhan, L., Ahmed, H., Hussein, H., Abbas, I.O., Al-Zuheiry Saba, R.S., (2013). Hind. A. Univ. J. Mater. Sci. 1:52-55. [2] Sarychev, K., Bergman, D.J., and Yagil, Y., (1995). Theory of The Optical and Microwave Properties of Metal-Dielectric Films. Physical Review B. 51:5366–5385. [3] Helmuth, H.J., (2009). Quant. Spectrodc. Ra. 110:787–799. [4] Yoochan, H., Yong, M.H., Dae, S.Y., and Jaemoon, Y.J., (1012). Nanobiosensors Based on Localized Surface Plasmon Resonance for Biomarker Detection. Journals of Nanomater. 1-13, ID:759830. [5] Link, S., and El-Sayed, M.A.J., (1999). Physical Chem B 1999, 103, 8410–8426. [6] Prasad, A.K., Kubinski, D.J., and Gouma, P.I., (2003). Sensor. Actuator. B. 93:25–30. [7] Granqvist, C.G., (1995). Handbook of Inorganic Electrochromic Materials, 1st ed. Elsevier, Amsterdam, The Netherlands. [8] Hinokuma, K., Kishimoto, A., and Kudo, T.J., (1994). Electrochem. Soc. 141:876–879. [9] Scarminio, J. and Lourenc, A., (1997). Gorenstein, A. Thin. Solid. Films. 302:66–70. [10] Gretener, C., Perrenoud, J., Kranz, L., Baechler, C., Yoon, S., Romanyuk, Y.E., Buecheler, S., and Tiwari, A.N., (2013). Thin. Solid. Films. 535:193–197. [11] Tarsame, S.S. and Reddy, G.B.J., (2005). Appl. Phys. 98:1-9, ID:026104. [12] Patil, R.S., Uplane, M.D., and Patil, P.S., (2006). Structural and Optical Properties of Electrodeposited Molybdenum Oxide Thin Films, Appl. Surf. Sci. 252:8050–8056, Elsivier. [13] Itoh, T., Matsubara, I., Shin, W., Izu, N., and Nishibori, M., (2008). Preparation of Layered Organic–Inorganic Nanohybrid Thin Films of Molybdenum Trioxide with Polyaniline Derivatives for Aldehyde Gases Sensors of Several Tens PPB Level, Sensor and Actuators B:Chemical, 128:512–520, Elsivier. [14] Seham, H.S., Esraa, A.A., Enas Y.A., and Shaimaa, A.A., (2016). Effect of Gamma Irradiation on The Optical Properties of (PVA: CuCl2) Films, Iraqi Academic Scientific Journals, 57:1968-1974. [15] Omed, G.A., Bakhtyar, K.A., and Sarkawt, A.H.J., (2013). Chem. Mater. Res. 3:84-90, Elsivier. [16] Elimat, Z.M., Zihlif, A.M., and Ragosta, G., (2010). Physica B. 405:3756-3760, Elsivier. [17] Moret, M.P., Devillers, M.A.C., Worhoff, K., and Larsen, P.K.J., (2002). Appl. Phys. 92:468-47, Elsivier. [18] Wemple, S.H. and DiDomenico. M., (1971). Phys. Rev. B3, 1338-1351, Elsivier. [19] Omed, G.A., Yahya, A.K.S., and Salwan, A.S., (2015). Phys. Mater. Chem. 3:18-24, Elsivier. [20] Wasan, A.A., Mohammed, T.A., and Tagreed, K.A., (2011). The MR affect on Optical Properties for Poly (Vinyl alcohol) Films. Baghdad Science Journal, 8:543-550. [21] Shehap, A.M. and Dana, S.A., (2016). Int. J. Nanoelectronics and Materials. 9:17-36. [22] Ghaleb, A.W.A., Hussein, N.N., Ahmed, B., Rafia, T., (2012). Brit. J. Sci. 4:117-124. [23] Mansour, A.F., Mansour, S.F., and Abdo, M.A.J., (2015). Improvement Structural and Optical Properties of ZnO/PVA Nanocomposites, Jounal of Applied Physics, 7:60-69. [24] Omed, G.A., Dlear, R.S., Sherzad, A.T., (2015). The Optical Characterization of Polyvinyl Alcohol: Cobalt Nitrate Solid Polymer Electrolzte Films. Advenced Materials Letters. 6:153-157. [25] Alias, A.N., Zabidi, Z.M., Ali, A.M.M., Harun, M.K., and Yahya, M.Z.A., (2013). Int. J. Appl. Sci. Techn. 3:11-38, Wiley.
Ayrıntılar
| Birincil Dil | Türkçe |
|---|---|
| Konular | Mühendislik |
| Bölüm | Kimya |
| Yazarlar | |
| Yayımlanma Tarihi | 13 Ekim 2018 |
| Yayımlandığı Sayı | Yıl 2018 Cilt: 13 Sayı: 4 |