Giant electrocaloric effect in high-polar-entropy perovskite oxides

Feihong Du; Tiannan Yang; Hua Hao; Shangshu Li; Chenhang Xu; Tian Yao; Zhiwu Song; Jiahe Shen; Chenyun Bai; Ruhong Luo; Donglin Han; Qiang Li; Shanyu Zheng; Yingjing Zhang; Yezhan Lin; Zhenhua Ma; Haotian Chen; Chenyu Guo; Jiawang Feng; Shengyi Zhong; Ruilin Mai; Guodong Hou; Haixin Qiu; Meng Xie; Xin Chen; Yakun Yuan; Dong Qian; Dao Xiang; Xuefeng Chen; Zhengqian Fu; Genshui Wang; Hanxing Liu; Jiangping Chen; Guang Meng; Xiangyang Zhu; Long Qing Chen; Shujun Zhang; Xiaoshi Qian

doi:10.1038/s41586-025-08768-8

Giant electrocaloric effect in high-polar-entropy perovskite oxides

Feihong Du, Tiannan Yang, Hua Hao, Shangshu Li, Chenhang Xu, Tian Yao, Zhiwu Song, Jiahe Shen, Chenyun Bai, Ruhong Luo, Donglin Han, Qiang Li, Shanyu Zheng, Yingjing Zhang, Yezhan Lin, Zhenhua Ma, Haotian Chen, Chenyu Guo, Jiawang Feng, Shengyi ZhongRuilin Mai, Guodong Hou, Haixin Qiu, Meng Xie, Xin Chen, Yakun Yuan, Dong Qian, Dao Xiang, Xuefeng Chen, Zhengqian Fu, Genshui Wang, Hanxing Liu, Jiangping Chen, Guang Meng, Xiangyang Zhu, Long Qing Chen, Shujun Zhang, Xiaoshi Qian

Research output: Contribution to journal › Article › peer-review

Abstract

Materials with a high electrocaloric effect (ECE)^1,2 tend to favour a disordered yet easily tunable polar structure. Perovskite ferroelectrics³ stand out as ideal candidates owing to their high dielectric responses and reasonable thermal conductivity. The introduction of multielement atomic distortions induces a high-polar-entropy state⁴ that notably increases the ECE by effectively overcoming the constraints imposed by highly ordered, polar-correlated perovskite structures. Here we developed a lead-free relaxor ferroelectric with strong polar disorder through targeted multielement substitution at both the A and B sites of the perovskite, effectively distorting the lattice structure and inducing a variety of nanoscale polar configurations, polymorphic polar variants and non-polar regions. A combination of these multielement-induced features led to an increased density of interfaces, significantly enhancing the polar entropy. Remarkably, a high ECE for an entropy change of about 15 J kg⁻¹ K⁻¹ under a 10 MV m⁻¹ field is observed for the material across a broad temperature range exceeding 60 °C. The formation of ultrafine, dispersed, multiphase lattice configurations leads to high-polar-entropy ferroelectric oxides with a high ECE and a long lifetime of over 1 million cycles that are suitable for manufacturing multilayer ceramic capacitors for practical electrocaloric refrigeration applications.

Original language	English (US)
Article number	5717
Pages (from-to)	924-930
Number of pages	7
Journal	Nature
Volume	640
Issue number	8060
DOIs	https://doi.org/10.1038/s41586-025-08768-8
State	Published - Apr 24 2025

All Science Journal Classification (ASJC) codes

General

Access to Document

10.1038/s41586-025-08768-8

Cite this

@article{935453fb9e394d7aa145ae4f2593dacd,

title = "Giant electrocaloric effect in high-polar-entropy perovskite oxides",

abstract = "Materials with a high electrocaloric effect (ECE)1,2 tend to favour a disordered yet easily tunable polar structure. Perovskite ferroelectrics3 stand out as ideal candidates owing to their high dielectric responses and reasonable thermal conductivity. The introduction of multielement atomic distortions induces a high-polar-entropy state4 that notably increases the ECE by effectively overcoming the constraints imposed by highly ordered, polar-correlated perovskite structures. Here we developed a lead-free relaxor ferroelectric with strong polar disorder through targeted multielement substitution at both the A and B sites of the perovskite, effectively distorting the lattice structure and inducing a variety of nanoscale polar configurations, polymorphic polar variants and non-polar regions. A combination of these multielement-induced features led to an increased density of interfaces, significantly enhancing the polar entropy. Remarkably, a high ECE for an entropy change of about 15 J kg−1 K−1 under a 10 MV m−1 field is observed for the material across a broad temperature range exceeding 60 °C. The formation of ultrafine, dispersed, multiphase lattice configurations leads to high-polar-entropy ferroelectric oxides with a high ECE and a long lifetime of over 1 million cycles that are suitable for manufacturing multilayer ceramic capacitors for practical electrocaloric refrigeration applications.",

author = "Feihong Du and Tiannan Yang and Hua Hao and Shangshu Li and Chenhang Xu and Tian Yao and Zhiwu Song and Jiahe Shen and Chenyun Bai and Ruhong Luo and Donglin Han and Qiang Li and Shanyu Zheng and Yingjing Zhang and Yezhan Lin and Zhenhua Ma and Haotian Chen and Chenyu Guo and Jiawang Feng and Shengyi Zhong and Ruilin Mai and Guodong Hou and Haixin Qiu and Meng Xie and Xin Chen and Yakun Yuan and Dong Qian and Dao Xiang and Xuefeng Chen and Zhengqian Fu and Genshui Wang and Hanxing Liu and Jiangping Chen and Guang Meng and Xiangyang Zhu and Chen, {Long Qing} and Shujun Zhang and Xiaoshi Qian",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2025.",

year = "2025",

month = apr,

day = "24",

doi = "10.1038/s41586-025-08768-8",

language = "English (US)",

volume = "640",

pages = "924--930",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "8060",

}

Du, F, Yang, T, Hao, H, Li, S, Xu, C, Yao, T, Song, Z, Shen, J, Bai, C, Luo, R, Han, D, Li, Q, Zheng, S, Zhang, Y, Lin, Y, Ma, Z, Chen, H, Guo, C, Feng, J, Zhong, S, Mai, R, Hou, G, Qiu, H, Xie, M, Chen, X, Yuan, Y, Qian, D, Xiang, D, Chen, X, Fu, Z, Wang, G, Liu, H, Chen, J, Meng, G, Zhu, X, Chen, LQ, Zhang, S & Qian, X 2025, 'Giant electrocaloric effect in high-polar-entropy perovskite oxides', Nature, vol. 640, no. 8060, 5717, pp. 924-930. https://doi.org/10.1038/s41586-025-08768-8

TY - JOUR

T1 - Giant electrocaloric effect in high-polar-entropy perovskite oxides

AU - Du, Feihong

AU - Yang, Tiannan

AU - Hao, Hua

AU - Li, Shangshu

AU - Xu, Chenhang

AU - Yao, Tian

AU - Song, Zhiwu

AU - Shen, Jiahe

AU - Bai, Chenyun

AU - Luo, Ruhong

AU - Han, Donglin

AU - Li, Qiang

AU - Zheng, Shanyu

AU - Zhang, Yingjing

AU - Lin, Yezhan

AU - Ma, Zhenhua

AU - Chen, Haotian

AU - Guo, Chenyu

AU - Feng, Jiawang

AU - Zhong, Shengyi

AU - Mai, Ruilin

AU - Hou, Guodong

AU - Qiu, Haixin

AU - Xie, Meng

AU - Chen, Xin

AU - Yuan, Yakun

AU - Qian, Dong

AU - Xiang, Dao

AU - Chen, Xuefeng

AU - Fu, Zhengqian

AU - Wang, Genshui

AU - Liu, Hanxing

AU - Chen, Jiangping

AU - Meng, Guang

AU - Zhu, Xiangyang

AU - Chen, Long Qing

AU - Zhang, Shujun

AU - Qian, Xiaoshi

PY - 2025/4/24

Y1 - 2025/4/24

N2 - Materials with a high electrocaloric effect (ECE)1,2 tend to favour a disordered yet easily tunable polar structure. Perovskite ferroelectrics3 stand out as ideal candidates owing to their high dielectric responses and reasonable thermal conductivity. The introduction of multielement atomic distortions induces a high-polar-entropy state4 that notably increases the ECE by effectively overcoming the constraints imposed by highly ordered, polar-correlated perovskite structures. Here we developed a lead-free relaxor ferroelectric with strong polar disorder through targeted multielement substitution at both the A and B sites of the perovskite, effectively distorting the lattice structure and inducing a variety of nanoscale polar configurations, polymorphic polar variants and non-polar regions. A combination of these multielement-induced features led to an increased density of interfaces, significantly enhancing the polar entropy. Remarkably, a high ECE for an entropy change of about 15 J kg−1 K−1 under a 10 MV m−1 field is observed for the material across a broad temperature range exceeding 60 °C. The formation of ultrafine, dispersed, multiphase lattice configurations leads to high-polar-entropy ferroelectric oxides with a high ECE and a long lifetime of over 1 million cycles that are suitable for manufacturing multilayer ceramic capacitors for practical electrocaloric refrigeration applications.

AB - Materials with a high electrocaloric effect (ECE)1,2 tend to favour a disordered yet easily tunable polar structure. Perovskite ferroelectrics3 stand out as ideal candidates owing to their high dielectric responses and reasonable thermal conductivity. The introduction of multielement atomic distortions induces a high-polar-entropy state4 that notably increases the ECE by effectively overcoming the constraints imposed by highly ordered, polar-correlated perovskite structures. Here we developed a lead-free relaxor ferroelectric with strong polar disorder through targeted multielement substitution at both the A and B sites of the perovskite, effectively distorting the lattice structure and inducing a variety of nanoscale polar configurations, polymorphic polar variants and non-polar regions. A combination of these multielement-induced features led to an increased density of interfaces, significantly enhancing the polar entropy. Remarkably, a high ECE for an entropy change of about 15 J kg−1 K−1 under a 10 MV m−1 field is observed for the material across a broad temperature range exceeding 60 °C. The formation of ultrafine, dispersed, multiphase lattice configurations leads to high-polar-entropy ferroelectric oxides with a high ECE and a long lifetime of over 1 million cycles that are suitable for manufacturing multilayer ceramic capacitors for practical electrocaloric refrigeration applications.

UR - http://www.scopus.com/inward/record.url?scp=105002167044&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=105002167044&partnerID=8YFLogxK

U2 - 10.1038/s41586-025-08768-8

DO - 10.1038/s41586-025-08768-8

M3 - Article

C2 - 40205056

AN - SCOPUS:105002167044

SN - 0028-0836

VL - 640

SP - 924

EP - 930

JO - Nature

JF - Nature

IS - 8060

M1 - 5717

ER -

Giant electrocaloric effect in high-polar-entropy perovskite oxides

Abstract

All Science Journal Classification (ASJC) codes

Access to Document

Other files and links

Fingerprint

Cite this