Spline interpolation for trap spectroscopy analysis for two cyclic hydrocarbons
Vol. 36 No. 1204 (2015), Artykuły
Vol. 36 No. 1204 (2015)

Spline interpolation for trap spectroscopy analysis for two cyclic hydrocarbons

Artykuły
https://doi.org/10.34658/physics.2015.36.28-39
Published December 31, 2015
Sylwester Kania
1Institute of Physics, Lodz University of Technology
Janusz Kuliński
Centre of Mathematics and Physics, Lodz University of Technology
PDF

Keywords

1-acenaphthenol
9,10-dimethylanthracene
conductivity
electric characterization
trap spectroscopy
cubic spline

How to Cite

Kania, S., & Kuliński, J. (2015). Spline interpolation for trap spectroscopy analysis for two cyclic hydrocarbons. Scientific Bulletin. Physics, 36(1204), 28-39. https://doi.org/10.34658/physics.2015.36.28-39
ACM ACS APA ABNT Chicago Harvard IEEE MLA Turabian Vancouver

Download Citation

Endnote/Zotero/Mendeley (RIS) BibTeX

Abstract

Cubic spline interpolation gives a tool for obtaining good image of current-voltage characteristics for trap spectroscopy analysis without prior assumption about the trap distribution for 1-acenaphthenol and 9,10-dimethylanthracene.

https://doi.org/10.34658/physics.2015.36.28-39
PDF

References

Price S.L. 2008. From crystal structure prediction to polymorph prediction: interpreting the crystal energy landscape. Phys. Chem. Chem. Phys. 10: 1996-2009.

Nangia A. 2008. Conformational Polymorphism in Organic Crystals. Acc. Chem. Res. 41: 595-604.

Parravicini G.B., Campione M., Marabelli F., Moret M., Sassella A. 2012. Experimental assessment of nonergodicity in tetracene single crystals. Phys. Rev. B 86: 024107-1 – 024107-5.

Phan B.T., Jung C., Choi T., Lee J. 2007. Trap-Controlled Space-Charge-Limited Current Conduction in the Cr-Doped SrTiO3 Thin Films Deposited by Using Pulsed Laser Deposition. J. Korean Phys. Soc. 51: 664-668.

Grynko D.O., Dimitriev O.P., Smertenko P.S., Fedoryak O.M., Оpanasyuk A.S., Тirkusova N.V., Noskov Yu.V., Ogurtsov N.A., Pud A.A. 2013. Injection Spectroscopy of Deep Traps in Nanostructured Films of Cadmium Sulfide. Proc. NAP 2: 01NTF41- 1 - 01NTF41-4.

Krellner C., Haas S., Goldmann C., Pernstich K.P., Gundlach D.J., Batlogg B. 2007. Density of bulk trap states in organic semiconductor crystals: Discrete levels inducedby oxygen in rubene. Phys Rev. B 75: 245115-1 - 245115-5.

von Runge C. 1901. Über empirische Funktionen und die Interpolation zwischen äquidistanten Ordinaten. Z. Math. Phys. 46: 224-243.

El-Mikkawy M., Atlan F. 2014. Algorithms for Solving Linear Systems of Equations of Tridiagonal Type via Transformations. Appl. Math. 5: 413-422.

Gerschgorin S. 1931. Über die Abgrenzung der Eigenwerte einer Matrix. Bull l’Acad. Scie. URSS, sci. math. 6: 749-754.

Warren J., Weimer H. 2000. Subdivision schemes for variational splines. Rice University, Department of Computer Science Technical Report. CS-TR 00-354.1-30.

Haq K., Khan M.M., Xueyin J., Zhilin A., Xiaowen Z., Liang Z., Jun L. 2009. Estimation of electron mobility of n-doped 4, 7-diphenyl-1, 10-phenanthroline using space-charge-limited currents. J Semiconductors 30: 1140009-1 - 104009-4.

Karl N. 2001. Charge-Carrier Mobility in organic crystals. in: Organic Materials Conjugated Polymers and Low Molecular weight Organic Solids, eds. Farchioni R., Grosso G. 283-322. Berlin Heideberg: Springer-Verlag GmbH.

Nešpurek S., Sworakowski J. 1980. Evaluation of the validity of analytical equations describing steady-state space-charge-limited current-voltage characteristics. Czech. J. Phys. B 30: 1148-1156.

Nešpurek S., Sworakowski J. 1980. Use of space‐charge‐limited current measurements to determine the properties of energetic distributions of bulk traps. J. Appl. Phys. 51: 2098-2102.

Kania S., Kuliński J.,Marciniak B., Różycka-Sokołowska E. 2013. Some electrical properties of thin layers of 9,10-dimethylanthracene and 1-acenaphthenol. Sci. Bull. Tech. Univ. Lodz, Physics 34: 35-42.

Kania S., Kuliński J., Marciniak B., Różycka-Sokołowska E. 2014. Bipolar transport of charge carriers in thin films of 9,10-dimethylanthracene and 1-acenaphthenol. Sci. Bull. Tech. Univ. Lodz, Physics 35: 33-39.

Mark P., Helfrich W. 1962. Space Charge Limited Currents in Organic Crystals. J. App. Phys. 33: 205-215.

Kuzma M. 2006. Charge transport in thin layers of organic crystals. J. Phys. Conf. Ser. 30: 307-320.

Tagyev B.G., Asadullayeva C.G. 2010. Elektryceskye svoistvsa polikrystallov soedinenia ZnGa2Se4. Phys. Gov. Az. Trans. XXX: 154-160.

Manfredotti C., de Blasi C., Gallasini S.D., Micocci G., Ruggiero L., Tepore A. 1976. Analysis of SCLC curves by a new direct method. Phys. Stat. Sol. 36: 569-577.

Kania S., Kondrasiuk J., Bąk G.W. 2004. Influence of ambient atmosphere on charge transport in polycrystalline thin films of three simple aromatic hydrocarbons. Eur. Phys. J. E 15: 439-442.

Bagratishvili G.D., Dzhanelidze R.B., Jishishvili D.A., Piskanovskii L.V., Zyuganov A.N., Mikhelashvili V.N., Smertenko P.S. 1981. Mechanism of charge flow through the M-Ge3N4-GaAs Structure. Phys. stat. sol. (a) 65: 701-707.

Mikhelashivi V., Eisenstein G. 2001. Effect of annealing conditions on optical and electrical characteristics of titanium dioxide films deposited by electron beam evaporation. J. Appl Phys. 89: 3256-3269.

Dacuňa J., Salleo A. 2011. Modeling space-charge limited currents in organic semiconductors: exctracting trap density and mobility. Physical Review B 84: 195209-1 - 195209-9.

Downloads

Download data is not yet available.