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Possibility of controlling the conduction mechanism by choosing a specific doping element in a praseodymium manganite system
Electrical properties of Pr(0.7)Ca(0.3)Mn(0.9)X(0.1)O(3) (X = Co, Ni, Cr and Fe) systems have been investigated using impedance spectroscopy measurements. The reported results confirmed the role of cationic disorder on the transport properties of the doped Pr(0.7)Ca(0.3)MnO(3) system. For the case o...
Autores principales: | , , , , |
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Formato: | Online Artículo Texto |
Lenguaje: | English |
Publicado: |
The Royal Society of Chemistry
2020
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Materias: | |
Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9056803/ https://www.ncbi.nlm.nih.gov/pubmed/35519033 http://dx.doi.org/10.1039/d0ra03982a |
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author | Moualhi, Y. M'nassri, R. Rahmouni, H. Gassoumi, M. Khirouni, K. |
author_facet | Moualhi, Y. M'nassri, R. Rahmouni, H. Gassoumi, M. Khirouni, K. |
author_sort | Moualhi, Y. |
collection | PubMed |
description | Electrical properties of Pr(0.7)Ca(0.3)Mn(0.9)X(0.1)O(3) (X = Co, Ni, Cr and Fe) systems have been investigated using impedance spectroscopy measurements. The reported results confirmed the role of cationic disorder on the transport properties of the doped Pr(0.7)Ca(0.3)MnO(3) system. For the case of the substitution by Co and Ni and Fe transition metals, the lower temperature side has been marked by the activation of the hopping conductivity over the nearest sites. Moreover, the Shklovskii–Efros-variable range hopping conductivity mechanism has been observed in the case of the substitution by Cr element. In the high temperature range, the evolution of the resistance with temperature confirmed the activation of a hopping process. In such a temperature range, the conduction process of all the studied compounds is dominated by a thermally activated small polaron hopping mechanism. For the Pr(0.7)Ca(0.3)Mn(0.9)Cr(0.1)O(3) compound, AC studies have confirmed that the electrical conductance should be investigated in terms of an activated quantum mechanical tunneling process. At higher frequencies, the Pr(0.7)Ca(0.3)Mn(0.9)Fe(0.1)O(3) compound is characterized by the existence of a high frequency plateau. For the Pr(0.7)Ca(0.3)Mn(0.9)Fe(0.1)O(3) ceramic, the dispersive region of the spectrum has confirmed the activation of the correlated barrier hopping mechanism. Thus, the conductance is found to follow the double Jonscher power law only for the temperature range of [80 K, 200 K]. For the Pr(0.7)Ca(0.3)Mn(0.9)Ni(0.1)O(3) compound, the evolution of the frequency exponent has confirmed the activation of two conduction mechanisms. The non small polaron tunneling mechanism was activated at lower temperatures. Accordingly, the activation of the correlated barrier hopping mechanism was detected for the high temperature range. For Pr(0.7)Ca(0.3)Mn(0.9)Co(0.1)O(3) manganite, the coexistence of two conduction mechanisms (correlated barrier hopping and the non small polaron tunneling) is noticed. The latter's were activated in the whole of the explored temperature range. Using the scaling model, the spectra of both Pr(0.7)Ca(0.3)Mn(0.9)Cr(0.1)O(3) and Pr(0.7)Ca(0.3)Mn(0.9)Ni(0.1)O(3) compounds merge into a single master curve, which confirms the validity of the time temperature superposition principle. |
format | Online Article Text |
id | pubmed-9056803 |
institution | National Center for Biotechnology Information |
language | English |
publishDate | 2020 |
publisher | The Royal Society of Chemistry |
record_format | MEDLINE/PubMed |
spelling | pubmed-90568032022-05-04 Possibility of controlling the conduction mechanism by choosing a specific doping element in a praseodymium manganite system Moualhi, Y. M'nassri, R. Rahmouni, H. Gassoumi, M. Khirouni, K. RSC Adv Chemistry Electrical properties of Pr(0.7)Ca(0.3)Mn(0.9)X(0.1)O(3) (X = Co, Ni, Cr and Fe) systems have been investigated using impedance spectroscopy measurements. The reported results confirmed the role of cationic disorder on the transport properties of the doped Pr(0.7)Ca(0.3)MnO(3) system. For the case of the substitution by Co and Ni and Fe transition metals, the lower temperature side has been marked by the activation of the hopping conductivity over the nearest sites. Moreover, the Shklovskii–Efros-variable range hopping conductivity mechanism has been observed in the case of the substitution by Cr element. In the high temperature range, the evolution of the resistance with temperature confirmed the activation of a hopping process. In such a temperature range, the conduction process of all the studied compounds is dominated by a thermally activated small polaron hopping mechanism. For the Pr(0.7)Ca(0.3)Mn(0.9)Cr(0.1)O(3) compound, AC studies have confirmed that the electrical conductance should be investigated in terms of an activated quantum mechanical tunneling process. At higher frequencies, the Pr(0.7)Ca(0.3)Mn(0.9)Fe(0.1)O(3) compound is characterized by the existence of a high frequency plateau. For the Pr(0.7)Ca(0.3)Mn(0.9)Fe(0.1)O(3) ceramic, the dispersive region of the spectrum has confirmed the activation of the correlated barrier hopping mechanism. Thus, the conductance is found to follow the double Jonscher power law only for the temperature range of [80 K, 200 K]. For the Pr(0.7)Ca(0.3)Mn(0.9)Ni(0.1)O(3) compound, the evolution of the frequency exponent has confirmed the activation of two conduction mechanisms. The non small polaron tunneling mechanism was activated at lower temperatures. Accordingly, the activation of the correlated barrier hopping mechanism was detected for the high temperature range. For Pr(0.7)Ca(0.3)Mn(0.9)Co(0.1)O(3) manganite, the coexistence of two conduction mechanisms (correlated barrier hopping and the non small polaron tunneling) is noticed. The latter's were activated in the whole of the explored temperature range. Using the scaling model, the spectra of both Pr(0.7)Ca(0.3)Mn(0.9)Cr(0.1)O(3) and Pr(0.7)Ca(0.3)Mn(0.9)Ni(0.1)O(3) compounds merge into a single master curve, which confirms the validity of the time temperature superposition principle. The Royal Society of Chemistry 2020-09-11 /pmc/articles/PMC9056803/ /pubmed/35519033 http://dx.doi.org/10.1039/d0ra03982a Text en This journal is © The Royal Society of Chemistry https://creativecommons.org/licenses/by-nc/3.0/ |
spellingShingle | Chemistry Moualhi, Y. M'nassri, R. Rahmouni, H. Gassoumi, M. Khirouni, K. Possibility of controlling the conduction mechanism by choosing a specific doping element in a praseodymium manganite system |
title | Possibility of controlling the conduction mechanism by choosing a specific doping element in a praseodymium manganite system |
title_full | Possibility of controlling the conduction mechanism by choosing a specific doping element in a praseodymium manganite system |
title_fullStr | Possibility of controlling the conduction mechanism by choosing a specific doping element in a praseodymium manganite system |
title_full_unstemmed | Possibility of controlling the conduction mechanism by choosing a specific doping element in a praseodymium manganite system |
title_short | Possibility of controlling the conduction mechanism by choosing a specific doping element in a praseodymium manganite system |
title_sort | possibility of controlling the conduction mechanism by choosing a specific doping element in a praseodymium manganite system |
topic | Chemistry |
url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9056803/ https://www.ncbi.nlm.nih.gov/pubmed/35519033 http://dx.doi.org/10.1039/d0ra03982a |
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