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Journal of Materials Science

Erschienen in:

01.02.2015 | Original Paper

Electrical transport properties of polyvinyl alcohol–selenium nanocomposite films at and above room temperature

verfasst von: Subhojyoti Sinha, Sanat Kumar Chatterjee, Jiten Ghosh, Ajit Kumar Meikap

Erschienen in: Journal of Materials Science | Ausgabe 4/2015

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Abstract

Here, we report the DC and AC electrical properties of polyvinyl alcohol (PVA)–selenium (Se) nanocomposite films in the temperature (T) range 298 K ≤ T ≤ 420 K and in the frequency (f) range 120 Hz ≤ f ≤ 1 MHz. The introduction of selenium nanoparticles into the PVA matrix slightly increases the values of DC conductivity whose temperature dependency obeys Vogel–Fulcher–Tammann law. The AC conductivity follows a power law with frequency in which the temperature dependence of the frequency exponent suggests that the correlated barrier hopping is the dominant charge transport mechanism for the nanocomposite films. Comparative discussions with Dyre’s random free-energy barrier model have also been made in this regard. The increase in AC conductivity with increase in nanoparticles concentration was also observed and attributed to the corresponding increase in conducting channels in the PVA matrix. The real part of the dielectric constant increases either with increase in temperature or with increase in selenium nanoparticles loading into the polymer matrix, which may be attributed to the enhancement of interfacial polarization. The frequency dispersion of the dielectric spectra has been modeled according to the modified Cole–Cole equation. Well-defined peaks were appeared in the plotting of imaginary part of electric modulus with frequency above room temperature, which was fitted with suitable equations to account for the deviations from ideal Debye-type behavior. Though the current–voltage characteristics are linear at smaller voltages, it appreciably becomes nonlinear at higher voltages. This nonlinearity has been accounted in light of Werner’s model and back to back Schottky diode model.

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Alivisatos AP (1996) Semiconductor clusters, nanocrystals, and quantum dots. Science 271:933–937CrossRef

Haase MA, Qui J, DePuydt JM, Cheng H (1991) Blue-green laser diodes. Appl Phys Lett 59:1272–1274CrossRef

Sinha S, Chatterjee SK, Ghosh J, Meikap AK (2013) Structural characterization and observation of variable range hopping conduction mechanism at high temperature in CdSe quantum dot solids. J Appl Phys 113:093703CrossRef

Schlamp MC, Peng XG, Alivisatos AP (1997) Improved efficiencies in light emitting diodes made with CdSe(CdS) core/shell type nanocrystals and a semiconducting polymer. J Appl Phys 82:5837CrossRef

Sargent EH (2009) Infrared photovoltaics made by solution processing. Nat Photonics 3:325–331CrossRef

Genovese MP, Lightcap IV, Kamat PV (2012) Sun-believable solar paint. A transformative one-step approach for designing nanocrystalline solar cells. ACS Nano 6:865–872CrossRef

Berger LI (1997) Semiconductor materials. CRC Press, Boca Raton FL, p 198–203

Sinha S, Chatterjee SK, Ghosh J, Meikap AK (2013) Semiconducting selenium nanoparticles: Structural, electrical characterization, and formation of a back-to-back Schottky diode device. J Appl Phys 113:123704CrossRef

Hasan A, El Sayed AM, Morsi WM, El-Sayed S (2012) Influence of Cr₂O₃ nanoparticles on the physical properties of polyvinyl alcohol. J Appl Phys 112:093525CrossRef

10.

Bouzerara R, Achour S, Tabet N, Zerkout S (2011) Synthesis and characterization of ZnO/PVA composite nanofibres by electrospinning. Int J Nanopart 4:10–19CrossRef

11.

Zhang FM, Chang J, Eberhard B (2010) Dissolution of poly(vinyl alcohol)-modified carbon nanotubes in a buffer solution. New Carbon Mater 25:241–247CrossRef

12.

Hanafy TA (2012) Dielectric relaxation and alternating current conductivity of lanthanum, gadolinium, and erbium-polyvinyl alcohol doped films. J Appl Phys 112:034102CrossRef

13.

Mondal SP, Aluguri R, Ray SK (2009) Dielectric and transport properties of carbon nanotube–CdS nanostructures embedded in polyvinyl alcohol matrix. J Appl Phys 105:114317CrossRef

14.

Bhadra D, Sannigrahi J, Chaudhuri BK, Sakata H (2012) Enhancement of the transport and dielectric properties of graphite oxide nanoplatelets-polyvinyl alcohol composite showing low percolation threshold. Polym Compos 33:436–442CrossRef

15.

Senthil V, Badapanda T, Chithambararaj A, Bose AC, Mohapatra AK, Panigrahi S (2012) Dielectric relaxation behavior and electrical conduction mechanism in polymer-ceramic composites based on Sr modified Barium Zirconium Titanate ceramic. J Polym Res 19:9898CrossRef

16.

Senthil V, Badapanda T, Kumar SN, Kumar P, Panigrahi S (2012) Relaxation and conduction mechanism of PVA: BYZT polymer composites by impedance spectroscopy. J Polym Res 19:9838CrossRef

17.

Fernandes DM, Hechenleitner AAW, Lima SM, Andrade LHC, Caires ARL, Pineda EAG (2011) Preparation, characterization, and photoluminescence study of PVA/ZnO nanocomposite films. Mater Chem Phys 128:371–376CrossRef

18.

Chakraborty G, Gupta K, Meikap AK, Babu R, Blau WJ (2011) Anomalous electrical transport properties of polyvinyl alcohol-multiwall carbon nanotubes composites below room temperature. J Appl Phys 109:033707CrossRef

19.

Gandhi S, Nagalakshmi N, Baskaran I, Dhanalakshmi V, Gopinathan Nair MR, Anbarasan R (2010) Synthesis and characterization of nano-sized NiO and its surface catalytic effect on poly(vinyl alcohol). J Appl Polym Sci 118:1666–1674

20.

Mahmoud WE, Al-Ghamdi AA (2010) The influence of vanadium pentoxide on the structure and dielectric properties of poly(vinyl alcohol). Polym Int 59:1282–1288CrossRef

21.

Abdelaziz M, Ghannam MM (2010) Influence of titanium chloride addition on the optical and dielectric properties of PVA films. Phys B 405:958–964CrossRef

22.

Sinha S, Chatterjee SK, Ghosh J, Meikap AK (2014) Dielectric relaxation and ac conductivity behaviour of polyvinyl alcohol–HgSe quantum dot hybrid films. J Phys D Appl Phys 47:275301CrossRef

23.

Mahendia S, Tomar AK, Kumar S (2010) Electrical conductivity and dielectric spectroscopic studies of PVA–Ag nanocomposite films. J Alloys Compd 508:406–411CrossRef

24.

Bhajantri RF, Ravindrachary V, Harisha A, Crasta V, Nayak SP, Poojary B (2006) Microstructural studies on BaCl₂ doped poly(vinyl alcohol). Polymer 47:3591–3598CrossRef

25.

Lunkenheimer P, Bobnar V, Pronin AV, Ritus AI, Volkov AA, Loidl A (2002) Origin of apparent colossal dielectric constants. Phys Rev B 66:052105CrossRef

26.

El-kader FHA, Osman WH, Mahmoud KH, Basha MAF (2008) Dielectric investigations and ac conductivity of polyvinyl alcohol films doped with europium and terbium chloride. Phys B 403:3473–3484CrossRef

27.

Yakuphanoglua F, Aydogdua Y, Schatzschneiderb U, Rentschlerb E (2003) Electrical conductivity, dielectric permittivity and thermal properties of the compound aqua [bis(2-dimethylaminomethyl-4-NIT-phenolato)] copper(II) including NaCl impurity. Phys B 334:443–450CrossRef

28.

Cole KS, Cole RH (1941) Dispersion and absorption in dielectrics I. Alternating current characteristics. J Chem Phys 9:342

29.

Tandon RP, Hotchandani S (2001) Electrical conductivity of semiconducting tungsten oxide glasses. Phys Status Solidi A 185:453–460CrossRef

30.

Thongbai P, Tangwancharoen S, Yamwong T, Maensiri S (2008) Dielectric relaxation and dielectric response mechanism in (Li, Ti)-doped NiO ceramics. J Phys Condens Matter 20:395227CrossRef

31.

Asami K (2002) Characterization of heterogeneous systems by dielectric spectroscopy. Prog Polym Sci 27:1617–1659CrossRef

32.

Psarras GC, Manolakaki E, Tsangaris GM (2002) Electrical relaxations in polymeric particulate composites of epoxy resin and metal particles. Compos A 33:375–384CrossRef

33.

Ioannou G, Patsidis A, Psarras GC (2011) Dielectric and functional properties of polymer matrix/ZnO/BaTiO3 hybrid composites. Compos A 42:104–110CrossRef

34.

Jonscher AK (1983) Dielectric relaxation in solids. Chelsea Dielectric Press, London, p 316

35.

Almond DP, Hunter CC, West AR (1984) The extraction of ionic conductivities and hopping rates from ac conductivity data. J Mater Sci 19:3236–3248CrossRef

36.

Jonscher AK (1977) The ‘universal’ dielectric response. Nature 267:673–679CrossRef

37.

Long AR (1982) Frequency-dependent loss in amorphous semiconductors. Adv Phys 31:553–637CrossRef

38.

Austin IG, Mott NF (1969) Polarons in crystalline and non-crystalline materials. Adv Phys 18:41–102CrossRef

39.

Elliott SR (1987) Ac conduction in amorphous chalcogenide and pnictide semiconductors. Adv Phys 36:135–217CrossRef

40.

Austin IG, Mott NF (1969) Polarons in crystalline and non-crystalline materials. Adv Phys 18:41–102CrossRef

41.

Dyre JC (1988) The random free-energy barrier model for ac conduction in disordered solids. J Appl Phys 64:2456CrossRef

42.

Psarras GC (2006) Hopping conductivity in polymer matrix–metal particles composites. Compos A 37:1545–1553CrossRef

43.

McCrum NG, Read BE, Williams G (1967) An elastic and dielectric effects in polymeric solids. Wiley, New York, pp 180–182

44.

Kim JS (2001) Electric modulus spectroscopy of lithium tetraborate (Li₂B₄O₇) single crystal. J Phys Soc Jpn 70:3129–3133CrossRef

45.

Gonzalez-Campos JB et al (2012) Revisiting the thermal relaxations of poly(vinyl alcohol). J Appl Polym Sci 125:4082–4090CrossRef

46.

González-Campos JB, Prokhorov E, Sanchez IC et al (2012) Molecular dynamics analysis of PVA-AgnP composites by dielectric spectroscopy. J Nanomater 2012:11. doi:10.1155/2012/925750

47.

Macedo PB, Moynihan CT, Bose R (1972) The long time aspects of this correlation function, which are obtainable by bridge techniques at temperatures approaching the glass transition. Phys Chem Glasses 13:171–176

48.

Bergman R (2000) General susceptibility functions for relaxations in disordered systems. J Appl Phys 88:1356CrossRef

49.

Sinha S, Chatterjee SK, Ghosh J, Meikap AK (2014) Anomalous electrical transport properties of CdSe quantum dots at and below room temperature. Phys B 438:70–77CrossRef

50.

Linares A, Nogales A, Rueda DR, Ezquerra TA (2007) Molecular dynamics in PVDF/PVA blends as revealed by dielectric loss spectroscopy. J Polym Sci Part B Polym Phys 45:1653–1661CrossRef

51.

Upadhyay J, Kumar A (2014) Investigation of structural, thermal and dielectric properties of polypyrrole nanotubes tailoring with silver nanoparticles. Compos Sci Technol 97:55–62CrossRef

52.

Sze SM (1981) Physics of semiconductor devices, 2nd edn. Wiley, New York, p 119

53.

Aubry V, Meyer F (1994) Schottky diodes with high series resistance: limitations of forward I–V methods. J Appl Phys 76:7973–7984CrossRef

54.

Werner JH (1988) Schottky barrier and pn-junction I/V plots—small signal evaluation. Appl Phys A 47:291–300CrossRef

55.

Chiquito AJ et al (2012) Back-to-back Schottky diodes: the generalization of the diode theory in analysis and extraction of electrical parameters of nanodevices. J Phys Condens Matter 24:225CrossRef

Titel: Electrical transport properties of polyvinyl alcohol–selenium nanocomposite films at and above room temperature
verfasst von: Subhojyoti Sinha
Sanat Kumar Chatterjee
Jiten Ghosh
Ajit Kumar Meikap
Publikationsdatum: 01.02.2015
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 4/2015
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-014-8724-z

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