Caloric Effects in Perovskite Oxides
Perovskite oxides show an amazing diversity of electronic and magnetic properties along with a myriad of structural variants and phase transitions. Large thermal changes may be driven near the ferroic phase transitions in perovskite oxides using magnetic, electric, and stress fields to manipulate co...
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| Published in: | Advanced materials interfaces Vol. 6; no. 15 |
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| Main Authors: | , , |
| Format: | Journal Article |
| Language: | English |
| Published: |
Weinheim
John Wiley & Sons, Inc
01-08-2019
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| Online Access: | Get full text |
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| Abstract | Perovskite oxides show an amazing diversity of electronic and magnetic properties along with a myriad of structural variants and phase transitions. Large thermal changes may be driven near the ferroic phase transitions in perovskite oxides using magnetic, electric, and stress fields to manipulate conjugate order parameters. The ensuing magnetocaloric, electrocaloric, and mechanocaloric effects can be utilized for environment‐friendly and high‐efficiency solid‐state cooling applications. In this review the details of these caloric effects in perovskite oxides both from a chronological perspective and from the viewpoint of the recent advances in multiple caloric phenomena are described. The authors highlight the role of interfaces in oxide thin films for the different caloric effects and address some of the outstanding challenges for the fundamental understanding and practical implementation of perovskite oxides in solid state refrigeration.
Perovskite oxides show an amazing diversity of physical properties along with many interesting structural variants and phase transitions. Large thermal changes may be driven near the ferroic phase transitions in perovskite oxides using magnetic, electric, and stress fields to manipulate conjugate order parameters. The ensuing magnetocaloric, electrocaloric, and mechanocaloric effects can be utilized for environment‐friendly and high‐efficiency solid‐state cooling applications. |
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| AbstractList | Perovskite oxides show an amazing diversity of electronic and magnetic properties along with a myriad of structural variants and phase transitions. Large thermal changes may be driven near the ferroic phase transitions in perovskite oxides using magnetic, electric, and stress fields to manipulate conjugate order parameters. The ensuing magnetocaloric, electrocaloric, and mechanocaloric effects can be utilized for environment‐friendly and high‐efficiency solid‐state cooling applications. In this review the details of these caloric effects in perovskite oxides both from a chronological perspective and from the viewpoint of the recent advances in multiple caloric phenomena are described. The authors highlight the role of interfaces in oxide thin films for the different caloric effects and address some of the outstanding challenges for the fundamental understanding and practical implementation of perovskite oxides in solid state refrigeration. Perovskite oxides show an amazing diversity of electronic and magnetic properties along with a myriad of structural variants and phase transitions. Large thermal changes may be driven near the ferroic phase transitions in perovskite oxides using magnetic, electric, and stress fields to manipulate conjugate order parameters. The ensuing magnetocaloric, electrocaloric, and mechanocaloric effects can be utilized for environment‐friendly and high‐efficiency solid‐state cooling applications. In this review the details of these caloric effects in perovskite oxides both from a chronological perspective and from the viewpoint of the recent advances in multiple caloric phenomena are described. The authors highlight the role of interfaces in oxide thin films for the different caloric effects and address some of the outstanding challenges for the fundamental understanding and practical implementation of perovskite oxides in solid state refrigeration. Perovskite oxides show an amazing diversity of physical properties along with many interesting structural variants and phase transitions. Large thermal changes may be driven near the ferroic phase transitions in perovskite oxides using magnetic, electric, and stress fields to manipulate conjugate order parameters. The ensuing magnetocaloric, electrocaloric, and mechanocaloric effects can be utilized for environment‐friendly and high‐efficiency solid‐state cooling applications. |
| Author | Kar‐Narayan, Sohini Mukherjee, Devajyoti Barman, Abhisikta |
| Author_xml | – sequence: 1 givenname: Abhisikta surname: Barman fullname: Barman, Abhisikta organization: Indian Association for the Cultivation of Science – sequence: 2 givenname: Sohini orcidid: 0000-0002-8151-1616 surname: Kar‐Narayan fullname: Kar‐Narayan, Sohini organization: University of Cambridge – sequence: 3 givenname: Devajyoti surname: Mukherjee fullname: Mukherjee, Devajyoti email: sspdm@iacs.res.in organization: Indian Association for the Cultivation of Science |
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| SubjectTerms | caloric effects Cooling effects interfaces Magnetic properties Order parameters Oxides perovskite oxide Perovskites Phase transitions Refrigeration solid‐state refrigeration Stress distribution Thin films |
| Title | Caloric Effects in Perovskite Oxides |
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