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Year 2016, Volume: 17 Issue: 4, 717 - 723, 01.12.2016
https://doi.org/10.18038/aubtda.267118

Abstract

References

  • [1] Chintakula G, Rajaputra S, Singh V P. Schottky diodes on nanowires of copper phthalocyanine. Solar Energy Materials & Solar Cells 2010; 94: 34–39.
  • [2] Shah M, Sayyad M H, Karimov Kh S, Maroof-Tahir M, Investigation of the electrical properties of a surface-type Al/NiPc/Ag Schottky diode using I–V and C–V characteristics. Physica B 2010; 405: 1188–1192.
  • [3] Mukherjee B, Mukherjee M. Programmable memory in organic field-effect transistor based on lead phthalocyanine. Organic Electronics 2009; 10: 1282–1287.
  • [4] Yazıcı A, Dalbul N, Altındal A, Salih B, Bekaroğlu Ö, Partition coefficient-Lewis basicity correlation in four dioxycyclo butenedion-bridged novel ball-type phthalocyanines, Synthetic Metals. 2016; 212: 25–30.
  • [5] Şahin S, Altun S, Altındal A, Odabaş Z. Synthesis of novel azo-bridged phthalocyanines and their toluene vapour sensing properties, Sensors and Actuators B. 2015; 206: 601–608.
  • [6] Bechara R, Petersen J, Gernigon V, Lévˆeque P, Heiser T, Toniazzo V, Ruch D, Michel M. PEDOT:PSS-free organic solar cells using tetrasulfonic copper phthalocyanine as buffer layer. Solar Energy Materials & Solar Cells. 2012;98: 482–485.
  • [7] Sharma G D, Balarajua P, Sharma P S K, Roy M S. Charge conduction process and photoelectrical properties of Schottky barrier device based on sulphonated nickel phthalocyanine. Synthetic Metals. 2008:158;15;620-629.2008:158;
  • [8] Pakhomov G L, Leonov E S, Klimov A Y, Microelectron. J. 2007; 38: 682.
  • [9] Soliman H S, Farag A A M, Khosifan N M, El- Nahass M M. Electrical transport mechanisms and photovoltaic characterization of cobalt phthalocyanine on silicon heterojunctions. Thin Solid Films. 2008; 516: 8678.
  • [10] Yazıcı A, Dalbul N, Altındal A, Salih B, Bekaroğlu Ö. Ethanol sensing property of novel phthalocyanines substituted with3,4-dihydroxy-3-cyclobuten-1,2-dione. Sensors and Actuators B. 2014; 202: 14–22.

Conduction Mechanisms in Organic-based Rectifying Diode

Year 2016, Volume: 17 Issue: 4, 717 - 723, 01.12.2016
https://doi.org/10.18038/aubtda.267118

Abstract

The temperature dependent
current–voltage characteristics of Ag/ZnPc/p-Si Schottky barrier (SB) diode are
investigated in the temperature range of 300–450 K, and in the bias range of ± 1 V. By fitting the
experimental data to
space-charge limited conduction, bulk-limited Poole–Frenkel emission and
thermo-ionic emission theory, it was observed that these models can not be applied to evaluate
junction parameters for the investigated SB diode. Preliminary results
indicated that the charge transport
proceeds
by different mechanism for low and high values of the applied voltage under forward and reverse bias conditions. It
was found that the charge transport is governed by hopping processes for low
values of the forward bias. However, for higher values of the forward bias, the
charge transport controlled by the bulk limited procesess. The same voltage
dependence was also observed for reverse bias conditions. 

References

  • [1] Chintakula G, Rajaputra S, Singh V P. Schottky diodes on nanowires of copper phthalocyanine. Solar Energy Materials & Solar Cells 2010; 94: 34–39.
  • [2] Shah M, Sayyad M H, Karimov Kh S, Maroof-Tahir M, Investigation of the electrical properties of a surface-type Al/NiPc/Ag Schottky diode using I–V and C–V characteristics. Physica B 2010; 405: 1188–1192.
  • [3] Mukherjee B, Mukherjee M. Programmable memory in organic field-effect transistor based on lead phthalocyanine. Organic Electronics 2009; 10: 1282–1287.
  • [4] Yazıcı A, Dalbul N, Altındal A, Salih B, Bekaroğlu Ö, Partition coefficient-Lewis basicity correlation in four dioxycyclo butenedion-bridged novel ball-type phthalocyanines, Synthetic Metals. 2016; 212: 25–30.
  • [5] Şahin S, Altun S, Altındal A, Odabaş Z. Synthesis of novel azo-bridged phthalocyanines and their toluene vapour sensing properties, Sensors and Actuators B. 2015; 206: 601–608.
  • [6] Bechara R, Petersen J, Gernigon V, Lévˆeque P, Heiser T, Toniazzo V, Ruch D, Michel M. PEDOT:PSS-free organic solar cells using tetrasulfonic copper phthalocyanine as buffer layer. Solar Energy Materials & Solar Cells. 2012;98: 482–485.
  • [7] Sharma G D, Balarajua P, Sharma P S K, Roy M S. Charge conduction process and photoelectrical properties of Schottky barrier device based on sulphonated nickel phthalocyanine. Synthetic Metals. 2008:158;15;620-629.2008:158;
  • [8] Pakhomov G L, Leonov E S, Klimov A Y, Microelectron. J. 2007; 38: 682.
  • [9] Soliman H S, Farag A A M, Khosifan N M, El- Nahass M M. Electrical transport mechanisms and photovoltaic characterization of cobalt phthalocyanine on silicon heterojunctions. Thin Solid Films. 2008; 516: 8678.
  • [10] Yazıcı A, Dalbul N, Altındal A, Salih B, Bekaroğlu Ö. Ethanol sensing property of novel phthalocyanines substituted with3,4-dihydroxy-3-cyclobuten-1,2-dione. Sensors and Actuators B. 2014; 202: 14–22.
There are 10 citations in total.

Details

Subjects Engineering
Journal Section Articles
Authors

Çiğdem Oruç

Arden Erkol This is me

Ahmet Altındal

Publication Date December 1, 2016
Published in Issue Year 2016 Volume: 17 Issue: 4

Cite

APA Oruç, Ç., Erkol, A., & Altındal, A. (2016). Conduction Mechanisms in Organic-based Rectifying Diode. Anadolu University Journal of Science and Technology A - Applied Sciences and Engineering, 17(4), 717-723. https://doi.org/10.18038/aubtda.267118
AMA Oruç Ç, Erkol A, Altındal A. Conduction Mechanisms in Organic-based Rectifying Diode. AUJST-A. December 2016;17(4):717-723. doi:10.18038/aubtda.267118
Chicago Oruç, Çiğdem, Arden Erkol, and Ahmet Altındal. “Conduction Mechanisms in Organic-Based Rectifying Diode”. Anadolu University Journal of Science and Technology A - Applied Sciences and Engineering 17, no. 4 (December 2016): 717-23. https://doi.org/10.18038/aubtda.267118.
EndNote Oruç Ç, Erkol A, Altındal A (December 1, 2016) Conduction Mechanisms in Organic-based Rectifying Diode. Anadolu University Journal of Science and Technology A - Applied Sciences and Engineering 17 4 717–723.
IEEE Ç. Oruç, A. Erkol, and A. Altındal, “Conduction Mechanisms in Organic-based Rectifying Diode”, AUJST-A, vol. 17, no. 4, pp. 717–723, 2016, doi: 10.18038/aubtda.267118.
ISNAD Oruç, Çiğdem et al. “Conduction Mechanisms in Organic-Based Rectifying Diode”. Anadolu University Journal of Science and Technology A - Applied Sciences and Engineering 17/4 (December 2016), 717-723. https://doi.org/10.18038/aubtda.267118.
JAMA Oruç Ç, Erkol A, Altındal A. Conduction Mechanisms in Organic-based Rectifying Diode. AUJST-A. 2016;17:717–723.
MLA Oruç, Çiğdem et al. “Conduction Mechanisms in Organic-Based Rectifying Diode”. Anadolu University Journal of Science and Technology A - Applied Sciences and Engineering, vol. 17, no. 4, 2016, pp. 717-23, doi:10.18038/aubtda.267118.
Vancouver Oruç Ç, Erkol A, Altındal A. Conduction Mechanisms in Organic-based Rectifying Diode. AUJST-A. 2016;17(4):717-23.