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Integrated Ferroelectrics
An International Journal
Volume 183, 2017 - Issue 1
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Original Articles

Equivalent circuit models using CPE for impedance spectroscopy of electronic ceramics

Shukdev PandeyDepartment of Ceramic Engineering, IIT(BHU), Varanasi, IndiaCorrespondence[email protected] [email protected]
,
Devendra KumarDepartment of Ceramic Engineering, IIT(BHU), Varanasi, India
,
Om ParkashDepartment of Ceramic Engineering, IIT(BHU), Varanasi, India
&
Lakshman PandeyDepartment of Physics and Electronics, Rani Durgavati University, Jabalpur, India
Pages 141-162 | Received 19 Mar 2017, Accepted 23 Aug 2017, Published online: 11 Dec 2017

References

  • A. J. Moulson, and J. M. Herbert, Electro-ceramics, England, John Wiley & Sons Ltd (2003).
  • R. C. Buchanan, Ceramic Materials for Electronics, CRC Press (2004).
  • M. T. Sebastian, Dielectric Materials for Wireless Communications, Elsevier Ltd. (2008).
  • E. Barsoukov, and J. Ross Macdonald, Impedance Spectroscopy Theory, Experiment, and Applications, Second edition, New Jersey, John Wiley & Sons, Inc. (2005).
  • A. K. Jonscher, Dielectric Relaxation in Solids, Chelsea Dielectric Press, London, (1983).
  • D. C. Sinclair, and A. R. West, Effect of Atmosphere on the PTCR properties of BaTiO3 ceramics, J.Mater. Sc. 29 (23), 6061–6068 (1994).
  • L. Pandey, O. Parkash, R. K. Katare, and D. Kumar, Equivalent circuit models for electronic ceramics, Bull. Matter. Sci. 18 (5), 563–576 (1995).
  • R. K. Katare, L. Pandey, R. K.Dwivedi, O. Parkash, and D. Kumar, A novel approach based on impedance spectroscopy for measurement of magnetic permeability of ceramics, Ind. J. of Engineering and Materials Science 6 (1), 34–42 (1999).
  • R. K. Katare, Application of Impedance Spectroscopy in the study of Electronic Ceramics, Ph.D. Thesis, Rani Durgavati University, Jabalpur, India (1997).
  • P. Chaitanya, Impedance Spectroscopy and RF Pulse Response of Piezoelectric Materials, Ph.D. Thesis, Rani Durgavati University, Jabalpur, India (2009).
  • P. Chaitanya, A. Shukla, and L. Pandey, Determination of Equivalent Circuit Model Components of Piezoelectric Materials by Using Impedance Spectroscopy, Integrated Ferroelectrics 150 (1), 88–95 (2014).
  • P. Chaitanya, R. Mishra, P. K. Ahirwal, A. Shukla, O. P. Thakur, L. Pandey, O. Parkash, and D. Kumar, Study of Temperature Dependence of Electrode–Glass Ceramic Interface Using Impedance Spectroscopy, Integrated Ferroelectrics 159 (1), 121–126 (2015).
  • P. Chaitanya, O. P. Thakur, V. Kumar, A. Shukla, and L. Pandey, Equivalent circuit model of a PbZr0.6Ti0.4O3 ceramic using impedance spectroscopy, Journal of Ceramic Processing Research 12 (3), 247–258 (2011).
  • L. Pandey, R. K. Katare, O. Parkash, D. Kumar, and O. P. Thakur, Complex Impedance Analysis of Electronic Ceramics showing steeply rising impedance pattern at low frequency, Ind. J. Pure & Appl. Physics 36 (4), 228–235 (1998).
  • H. S. Maiti, and R. N. Basu, Complex plane impedance analysis for semiconducting barium titanate, Mat. Res. Bull. 21 (9), 1107–1114 (1986).
  • L. Pandey, R. K. Katare, O. Parkash, and D. Kumar, Evidence of Two Ferroelectric PTCR components in valence compensated ceramic system Ba1-x Lax Ti1-x CoxO3, Bull. Mater. Sc. 20 (7), 933–947 (1997).
  • V. Kumar, O. P. Thakur, L.Pandey, A. P. Guimaraes, A. Goel, O. Parkash, and D. Kumar, Modeling of Electrical Behavior of La0.7Ca0.3MnO3 Ceramic using Impedance Spectroscopy, Modern Physics Letters B 19 (15), 697–706 (2005).
  • S. Kochowski, and K Nitsch, Description of the frequency behaviour of metal–SiO2–GaAs structure characteristics by electrical equivalent circuit with constant phase element, Thin Solid Films 415 (1–2), 133–137 (2002).
  • J. Z. Bao, C. C. Davis, and R. E. Schmuckler, Frequency Domain impedance measurements of erythrocytes: Constant Phase Angle impedance characteristics and phase transition, Biophysics J. 61 (5), 1427–1434 (1992).
  • S. Grimnes, O. Grottem Martinsen, Bioimpedance and Bioelectricity Basics, Third Edition, Academic Press, New York, 303 (2015).
  • S. Schreiner, J. D. Bronzino, and D. R. Peterson, Medical Instruments and Devices: Principles and Practices, CRC Press (2016).
  • D. Manic, V. Paunovic, M. Vijatovic, B. Stojanovic, and L. Zivkovic, Electrical Characterization and Impedance Response of Lanthanum doped Barium Titanate Ceramics, Science of Sintering 40 (3), 283–294 (2008).
  • L. Wang, J. Zhao, X. He, J. Gao, J. Li, C. Wan, C. Jiang, Electrochemical Impedance Spectroscopy (EIS) Study of LiNi1/3Co1/3Mn1/3O2 for Li-ion Batteries, Int. J. Electrochem. Sc. 7 (1), 345–353 (2012).
  • J. P. Diard, B. Le Gorrec, and C. Montella, Handbook of Electrochemical Impedance Spectroscopy, Hosted by [email protected], March 29 (2013).
  • S. Das, M. Sivaramakrishna, B. Goswami, and K. Biswas, Design of a Low-Cost Constant Phase Angle Based Sensor System to Detect Natural Milk and Synthetic –Milk Reconstructed from Liquid- Whey, SENSORCOMM 2011: Proceedings of The Fifth International Conference on Sensor Technologies and Applications, Aug 21–27, (French Riviera, Nice/Saint Laurent du Var, France) 307–311 (2011).
  • D. Mancic, V. Paunovic, Z. Petrusic, M. Radmanovic, and L. Zivkovic, Application of Impedance Spectroscopy for Electrical Characterization of Ceramic Materials, Electronics 13 (1), 11–17 (2009).
  • R. K. Katare, L. Pandey, O. P. Thakur, O. Parkash, and D. Kumar, Equivalent Circuit Model of Ca1- xYxTi1-xCoxO3 Using Impedance Spectroscopy, Modern Physics Letters B 17 (8), 339–346 (2003).
  • K. Chinen, I. Kinjo, A. Zamani, K. Ire, and K. Nagayama, New equivalent-electrical circuit model and a practical measurement method for human body impedance, Bio-Medical Materials and Engineering 26 (1), S779–S786 (2015).
  • P. M. Faia, C. S. Furtado, A. J. Ferreira, AC impedance spectroscopy: a new equivalent circuit for titania thick film humidity sensors, Sensors and Actuators B 107 (1), 353–359 (2005).
  • X. Wang, Non-Destructive Characterisation Of Structural Ceramics Using Impedance Spectroscopy, Ph.D. Thesis, Brunel University (2001).
  • C. Dalmay, M. Cheray, A. Pothier, F. Lalloue, M. O. Jauberteau, and P. Blondy, Ultra sensitive biosensor based on impedance spectroscopy at microwave frequencies for cell scale analysis, Sensors and Actuators A:Physical 62 (2), 189–197 (2010).
  • J. Estrela da Silva, J. P. Marques de Sa, and J. Jossinet, Classification of breast tissue by electrical impedance spectroscopy, Medical & Biological Engineering & Computing 38 (1), 26–30 (2000).
  • H. Tränkler, O. Kanoun, M. Mind, and M. Rist, Smart sensor systems using impedance spectroscopy, Proc. Estonian Acad. Sci. Eng. 13 (4), 455–478 (2007).
  • G. Bonmassar, S. Iwaki, G. Goldmakher, L. M. Angelone, J. W. Belliveau, and M. H. Lev, On the Measurement of Electrical Impedance Spectroscopy (EIS) of the Human Head, International Journal of Bioelectromagnetism 12 (1), 32–40 (2009).
  • D. McGivney, D. Calvetti, and E. Somersalo, Quantitative imaging with electrical impedance spectroscopy, Physics in Medicine and Biology 57 (22), 7289–7302 (2012).
  • S. F. Khalil, M. S. Mohktar, and F. Ibrahim, The Theory and Fundamentals of Bioimpedance Analysis in Clinical Status Monitoring and Diagnosis of Diseases, Sensors 14 (6), 10895–10928 (2014).
  • T. Okachi, T. Nagase, T. Kobayashi, and H. Naitoa, Determination of localized-state distributions in organic light-emitting diodes by impedance spectroscopy, Applied Physics Letters 94 (4), 043301–3 (2009).
  • J. Juansah, I. W. Budiastra, K. Dahlan, and K. B. Seminar, The Prospect of Electrical Impedance Spectroscopy as Non-destructive Evaluation of Citrus Fruits Acidity, International Journal of Emerging Technology and Advanced Engineering 2 (11), 58–63 (2012).
  • O. Kanoun, Lecture Notes on Impedance Spectroscopy: Measurement Modelling and Applications vol 1–5, CRC Press, Taylor and Francis group, London(UK), (2011).
  • M. E. Orazem, I. Frateur, B. Tribollet, V. Vivier, S. Marcelin, N. Pebere, A. L. Bunge, E. A. White, D. P. Riemer, and M. Musianif, Dielectric Properties of Materials showing Constant-Phase-Element (CPE) Impedance Response, Journal of The Electrochemical Society 160, C215–C225 (2013).
  • B. A. Boukamp, M. T. N. Pham, D. H. A. Blank, H. J. M.  , Bouwmeester, Ionic and Electronic Conductivity in Lead-Zirconate-Titanate (PZT), Solid State Ionics 170 (3–4), 239–254 (2004)
  • L. A. Dissado, and R. M. Hill, Constant-phase-angle and power-law regimes in the frequency response of a general determinate fractal circuit, Physical Review B 37 (7), 3434–3439 (1988).
  • B. Hirschorn, M. E. Orazem, B. Tribollet, V. Vivier, I. Frateur, and M. Musiani, Constant –Phase- Element Behaviour Caused by Resistivity Distributions in Films I.Theory, Journal of the Electrochemical Society 157 (12), C452–C457 (2010).
  • J. Lario-Garcıa, and R. Pallas-Areny, Constant-phase element identification in conductivity sensors using a single square wave, Sensors and Actuators A 132 (1), 122–128 (2006).
  • P. W. MacMillan, Glass Ceramics, 2nd Edition, Academic Press, London (1979).
  • W. D. Kingery, H. K. Bowen, and D. R. Uhlmann, Introduction to Ceramics, Second Edition, John Wiley & Sons, 368 (1976).
  • M. H. Lewis, Glass and Glass Ceramics, Chapman and Hall, London (1989).
  • A. Herczog, Application of Glass-Ceramics for Electronic Components and Circuits, IEEE Trans. Parts, Hybrids, Package PHP-9, 247–256 (1973).
  • G. Patridge, Glass –Ceramics – Wide Ranging Engineering Materials, Glass Production, Technology International, Edited by Rawson H. Sterling Publications International Ltd., London (1991).
  • G. Partridge, An overview of glass ceramics:Part1-development and principle bulk applications, Glass Technol. 35 (3), 116–127 (1994).
  • M. Casciola, and D. Fabiani, Ionic conduction and dielectric properties of anhydrous alkali metal salt forms of α-zirconium phosphate, Solid State Ionics 11, 31–38 (1983).
  • L. Pandey, in Workshop on use of computers in teaching physics, partly sponsored by ICTP, Jabalpur, India Dec 3–9 (1992).
  • H. Fricke, The theory of electrolytic polarization, Philos. Mag., 14 (90), 310–318 (1932).
  • K. S. Cole, and R. H. Cole, Dispersion and Absorption in Dielectrics I. Alternating Current Characteristics, J. Chem. Phys. 9 (4), 341–351 (1941).

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