Volume 4, Issue 11 p. 2891-2901
Article

Towards a Universal Approach for the Analysis of Impedance Spectra of Perovskite Solar Cells: Equivalent Circuits and Empirical Analysis

Dr. Anna Todinova

Corresponding Author

Dr. Anna Todinova

Physical Chemistry Section, University Pablo de Olavide, E-, 41013 Seville, Spain

Present address: Molecular Materials and Nanosystems, Eindhoven University of Technology, P.O. Box 513, 5600 MB Eindhoven, The Netherlands

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Lidia Contreras-Bernal

Lidia Contreras-Bernal

Physical Chemistry Section, University Pablo de Olavide, E-, 41013 Seville, Spain

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Manuel Salado

Manuel Salado

Physical Chemistry Section, University Pablo de Olavide, E-, 41013 Seville, Spain

Abengoa Research, C/Energía Solar n° 1, Campus Palmas Altas, 41014 Seville, Spain

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Dr. Shahzada Ahmad

Dr. Shahzada Ahmad

Abengoa Research, C/Energía Solar n° 1, Campus Palmas Altas, 41014 Seville, Spain

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Neftalí Morillo

Neftalí Morillo

Physical Chemistry Section, University Pablo de Olavide, E-, 41013 Seville, Spain

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Dr. Jesús Idígoras

Dr. Jesús Idígoras

Physical Chemistry Section, University Pablo de Olavide, E-, 41013 Seville, Spain

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Prof. Dr. Juan A. Anta

Corresponding Author

Prof. Dr. Juan A. Anta

Physical Chemistry Section, University Pablo de Olavide, E-, 41013 Seville, Spain

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First published: 17 July 2017
Citations: 95

Graphical Abstract

If the shoe fits: A general approach for the analysis of impedance spectra is demonstrated through empirical and equivalent circuit analysis. Different equivalent circuits (Voight, matryoshka, Maxwell, hybrid Voight-matryoshka) are investigated and compared for fitting the impedance response of perovskite solar cells.

Abstract

Impedance spectroscopy is a powerful electrochemical small-perturbation technique that provides dynamic electrical data in solar cells. This technique has been widely used to characterize dye-sensitized solar cells and perovskite solar cells (PSCs). Physical parameters are normally obtained by fitting to an equivalent circuit, composed of electrical elements which theoretically correspond to physical processes involved in the photoconversion process. A variety of equivalent circuits to model the impedance spectra of PSCs are commonly used by different research groups. In this work, we evaluate their performance and adequacy. We demonstrate the analytical and numerical equivalence of impedance expressions for Voight, matryoshka, and hybrid circuits, which are used to fit a typical impedance spectrum of a PSC and compare the resulting parameters to the empirical values obtained without any equivalent circuit. The numerical equivalence can be demonstrated by using two- and three-component impedance spectra. In contrast, Maxwell-type equivalent circuits reveal parameters that have a more complex relation to empirical values. The presence of inductive effects such as “loops” and “negative tails” in impedance spectra are also discussed in terms of negative values of resistances and capacitances. We propose a general protocol to analyze impedance data of PSCs and to extract useful information from them.

Conflict of interest

The authors declare no conflict of interest.