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Nonlinear Lock-In Infrared Microscopy: A Complementary Investigation Technique for the Analysis of Functional Electroceramic Components

Published online by Cambridge University Press:  14 May 2015

Michael Hofstätter ,
Nadine Raidl ,
Bernhard Sartory  and
Peter Supancic
Michael Hofstätter
Affiliation:
Institut für Struktur- und Funktionskeramik, Montanuniversitaet Leoben, 8700 Leoben, Austria
Nadine Raidl
Affiliation:
Institut für Struktur- und Funktionskeramik, Montanuniversitaet Leoben, 8700 Leoben, Austria
Bernhard Sartory
Affiliation:
Materials Center Leoben Forschung GmbH, Roseggerstraße 12, 8700 Leoben, Austria
Peter Supancic*
Affiliation:
Institut für Struktur- und Funktionskeramik, Montanuniversitaet Leoben, 8700 Leoben, Austria Materials Center Leoben Forschung GmbH, Roseggerstraße 12, 8700 Leoben, Austria
*
*Corresponding author. peter.supancic@unileoben.ac.at
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Abstract

Using lock-in infrared microscopy as a tool for current detection on the micrometer scale in AC-driven specimens in combination with iterative grinding procedure allows preparation of current dominating microstructure regions on well-polished surfaces. This technique is applied successfully on varistor components based on specially doped ZnO-based varistor ceramics. This peculiar electroceramic material exhibits exceptional high nonlinear current–voltage (I-V) characteristics, described by a power law according I~Vα, caused by double Schottky barriers at the grain boundaries. As a novelty the thermographic response is used to evaluate local electrical properties, namely the nonlinearity coefficient α, on basis of higher order harmonics with respect to the basic electrical driving AC-frequency.

To correlate the observed electrical properties to the microstructure, the polar crystal orientation of the relevant ZnO grains is determined by combining electron backscatter diffraction and orientation-dependent patterns as a result of a chemical etching procedure. These findings support a modified new model for describing the grain boundary controlled current flow in a varistor microstructure including orientation-dependent barrier properties. Hence, the experimentally observed current direction-dependent behavior can be described consistently.

Keywords

thermographyelectroceramic materialsSchottky barrierszinc oxidevaristor
Type
EMAS Special Issue
Information
Microscopy and Microanalysis , Volume 21 , Issue 5 , October 2015 , pp. 1145 - 1152
Copyright
© Microscopy Society of America 2015 

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Footnotes

This article is intended for the Special Issue from the EMAS 2014 Workshop on Electron Probe Microanalysis of Materials Today—Rare and Noble Elements: From Ore Deposits to High-Tech Materials.

References

Alim, M.A., Li, S., Liu, F. & Cheng, P. (2006). Electrical barriers in the ZnO varistor grain boundaries. Phys Status Solidi A 203, 410427.Google Scholar
Blatter, G. & Baeriswyl, D. (1987). High-field transport phenomenology hot-electron generation at semiconductor interfaces. Phys Rev B 36, 6446.Google Scholar
Blatter, G. & Greuter, F. (1986 a). Carrier transport through grain boundaries in semiconductors. Phys Rev B 33, 3952.CrossRefGoogle ScholarPubMed
Blatter, G. & Greuter, F. (1986 b). Electrical breakdown at semiconductor grain boundaries. Phys Rev B 34, 8555.CrossRefGoogle ScholarPubMed
Breitenstein, O., Langenkamp, M., Altmann, F., Katzer, D., Lindner, A. & Eggers, H. (2000). Microscopic lock-in thermography investigation of leakage sites in integrated circuits. Rev Sci Instrum 71, 4155.Google Scholar
Breitenstein, O., Warta, W. & Langenkamp, M. (2010). Lock-In Thermography: Basics and Use for Evaluating Electronic Devices and Materials. Berlin, Heidelberg: Springer-Verlag Berlin Heidelberg.Google Scholar
Busse, G., Wu, D. & Karpen, W. (1992). Thermal wave imaging with phase sensitive modulated thermography. J Appl Phys 71, 3962.Google Scholar
Clarke, D.R. (1999). Varistor ceramics. J Am Ceram Soc 82, 485502.CrossRefGoogle Scholar
Emtage, P.R. (1977). The physics of zinc oxide varistor. J Appl Phys 48, 4372.Google Scholar
Fujitsu, S., Toyoda, H. & Yanagida, H. (1987). Origin of ZnO varistor. J Am Ceram Soc 70, C-71C-72.Google Scholar
Greuter, F. (1995). Electrically active interfaces in ZnO varistors. Solid State Ionics 75, 6778.Google Scholar
Greuter, F. & Blatter, G. (1990). Electrical properties of grain boundaries in polycrystalline compound semiconductors. Semicond Sci Technol 5, 111137.CrossRefGoogle Scholar
Hofstätter, M., Nevosad, A., Teichert, C., Supancic, P. & Danzer, R. (2013). Voltage polarity dependent current paths through polycrystalline ZnO varistors. J Eur Ceram Soc 33, 34733476.CrossRefGoogle Scholar
Hofstätter, M. & Supancic, P. (2013). 3D Netzwerksimulationen von Varistoren mit verschiedenen Korngrößenverteilungen. Berg Huettenmaenn Monatsh 158, 206210.Google Scholar
Jo, W., Kim, S.J. & Kim, D.Y. (2005). Analysis of the etching behavior of ZnO ceramics. Acta Mater 53, 41854188.Google Scholar
Levinson, L.M. & Philipp, H.R. (1975). The physics of metal oxide varistors. J Appl Phys 46, 1332.Google Scholar
Li, H.H., Huang, Y.X., Li, Z.M., Yao, Y.H. & Zhang, S.Y. (2014). Preparation and infrared emissivities of alkali metal doped ZnO powders. J Cent South Univ 21, 34493455.CrossRefGoogle Scholar
Mahan, G.D. (1979). Theory of conduction in ZnO varistors. J Appl Phys 50, 27992812.CrossRefGoogle Scholar
Mariano, A.N. & Hanneman, R.E. (1963). Crystallographic polarity of ZnO crystals. J Appl Phys 34, 384.Google Scholar
Meola, C., Carlomagno, G.M. & Giorleo, L. (2004). The use of infrared thermography for materials characterization. J Mater Process Technol 155–156, 11321137.Google Scholar
Meola, C., Carlomagno, G.M., Squillace, A. & Vitiello, A. (2006). Non-destructive evaluation of aerospace materials with lock-in thermography. Eng Fail Anal 13, 380388.Google Scholar
Nevosad, A., Hofstätter, M., Supancic, P. & Teichert, C. (2014). Micro four-point probe investigation of individual ZnO grain boundaries in a varistor ceramic. J Eur Ceram Soc 34, 19631970.CrossRefGoogle Scholar
Pike, G.E. (1984). Semiconductor grain-boundary admittance theory. Phys Rev B 30, 795802.Google Scholar
Raidl, N., Supancic, P., Danzer, R. & Hofstätter, M. (2015). Piezotronically Modified Double Schottky Barriers in ZnO Varistors. Adv Mater 27, 20312035.Google Scholar
Rantala, J., Wu, D. & Busse, G. (1998). NDT of polymer materials using lock-in thermography with water-coupled ultrasonic excitation. NDT and E Int 31, 4349.Google Scholar
Sakagami, T. & Kubo, S. (2002). Applications of pulse heating thermography and lock-in thermography to quantitative nondestructive evaluations. Infrared Phys Technol 43, 211218.Google Scholar
Tanaka, A. & Mukae, K. (1999). ICTS measurements of single grain boundaries in ZnO: Rare-earth varistor. J Electroceram 4, 5559.Google Scholar
Tanaka, S. & Takahashi, K. (1999). Direct measurements of voltage–current characteristics of single grain boundary of ZnO varistors. J Eur Ceram Soc 19, 727730.Google Scholar
Verghese, P.M. & Clarke, D.R. (2000). Piezoelectric contributions to the electrical behavior of ZnO varistors. J Appl Phys 87, 44304438.Google Scholar
Zhang, Y., Liu, Y. & Wang, Z.L. (2011). Fundamental theory of piezotronics. Adv Mater 23, 30043013.Google Scholar
Zhou, J., Fei, P., Gu, Y., Mai, W., Gao, Y., Yang, R., Bao, G. & Wang, Z.L. (2008 a). Piezoelectric-potential-controlled polarity-reversible Schottky diodes and switches of ZnO wires. Nano Lett 8, 39733977.Google Scholar
Zhou, J., Gu, Y., Fei, P., Mai, W., Gao, Y., Yang, R., Bao, G. & Wang, Z.L. (2008 b). Flexible piezotronic strain sensor. Nano Lett 8, 30353040.Google Scholar