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Ferroelectrics Volume 90, 1989 - Issue 1
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Properties

X-ray studies of electrocaloric lead-scandium tantalate ordered solid solutions

L. A. Shebanov Institute of Solid State Physics, Latvian State University, 8, Kengaraga St., 226063, Riga, Latvian SSR, USSR
,
E. H. Birks Institute of Solid State Physics, Latvian State University, 8, Kengaraga St., 226063, Riga, Latvian SSR, USSR
&
K. J. Borman Institute of Solid State Physics, Latvian State University, 8, Kengaraga St., 226063, Riga, Latvian SSR, USSR
Pages 165-172 | Received 15 Sep 1988, Published online: 08 Feb 2011

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Satyanarayan Patel, Aditya Chauhan & Rahul Vaish. (2016) Large room temperature electrocaloric strength in bulk ferroelectric ceramics: an optimum solution. Phase Transitions 89:10, pages 1019-1028.
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E. Birks, M. Dunce & A. Sternberg. (2010) High Electrocaloric Effect in Ferroelectrics. Ferroelectrics 400:1, pages 336-343.
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V.V. Shvartsman, S.E. Aksenov & E.D. Politova. (2001) Phase relations and ferroelectric properties of Pb(Zr, Sn, Ti)O3 ceramics. Ferroelectrics 258:1, pages 13-20.
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Xiao Dingquan. (1999) Environmentally conscious ferroelectrics research—present and prospect. Ferroelectrics 231:1, pages 133-141.
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D.Q. Xiao, B. Yang, S.Q. Peng, Y.C. Wang & J.G. Zhu. (1997) Analyses and syntheses of ferroelectric refrigeration ceramics. Ferroelectrics 195:1, pages 93-96.
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L. Shebanovs, A. Sternberg, W.N. Lawless & K. Borman. (1996) Isomorphous ion substitutions and order-disorder phenomena in highly electrocaloric lead-scandium tantalate solid solutions. Ferroelectrics 184:1, pages 239-242.
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L. Shebanov & K. Borman. (1992) On lead-scandium tantalate solid solutions with high electrocaloric effect. Ferroelectrics 127:1, pages 143-148.
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Articles from other publishers (23)

Zhenglyu Li, Christian Molin, Alexander Michaelis & Sylvia E. Gebhardt. (2023) Modified (Ba,Sr)(Sn,Ti)O3 via hydrothermal synthesis for electrocaloric application. Open Ceramics 16, pages 100502.
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Yanzhou Lu, Xiaofan Sun, Min Zhao, Shulin Jiao, Dong Li, Peng Chen, Wentao Zhang, Kongmeng Ye, Libo Xu, Qi You, Hong-Ling Cai & XiaoShan Wu. (2023) Enhanced Electrocaloric Effect of Lead Scandium Tantalate by Zirconium Doping. ACS Applied Materials & Interfaces 15:44, pages 51252-51261.
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Vladimir V. Shvartsman, Yusra Hambal & Doru C. Lupascu. 2023. The Electrocaloric Effect. The Electrocaloric Effect 303 332 .
Gunnar Suchaneck. 2023. The Electrocaloric Effect. The Electrocaloric Effect 175 204 .
Youri Nouchokgwe, Pierre Lheritier, Tomoyasu Usui, Alvar Torello, Asmaa El Moul, Veronika Kovacova, Torsten Granzow, Sakyo Hirose & Emmanuel Defay. (2022) Materials efficiency of electrocaloric lead scandium tantalate multilayer capacitors. Scripta Materialia 219, pages 114873.
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Youri Nouchokgwe, Pierre Lheritier, Chang-Hyo Hong, Alvar Torelló, Romain Faye, Wook Jo, Christian R. H. Bahl & Emmanuel Defay. (2021) Giant electrocaloric materials energy efficiency in highly ordered lead scandium tantalate. Nature Communications 12:1.
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G. A. Gavrilov, G. Yu. Sotnikova, A. V. Sotnikov & E. P. Smirnova. (2020) Interrelation of electrocaloric and concomitant effects in lead magnesium niobate based ceramics. Journal of Materials Science 55:16, pages 6783-6793.
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S. Crossley, B. Nair, R. W. Whatmore, X. Moya & N. D. Mathur. (2019) Electrocaloric Cooling Cycles in Lead Scandium Tantalate with True Regeneration via Field Variation. Physical Review X 9:4.
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Abhisikta Barman, Sohini Kar‐Narayan & Devajyoti Mukherjee. (2019) Caloric Effects in Perovskite Oxides. Advanced Materials Interfaces 6:15, pages 1900291.
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E. P. Smirnova, G. Yu. Sotnikova, N. V. Zaitseva, A. A. Kapralov, G. A. Gavrilov & A. V. Sotnikov. (2018) Electrocaloric Effect in a Lead Magnoniobate–Scandoniobate Relaxor. Physics of the Solid State 60:10, pages 2006-2011.
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Fangping Zhuo, Qiang Li, Jinghan Gao, Yongjie Ji, Qingfeng Yan, Yiling Zhang, Hong-Hui Wu, Xiao-Qing Xi, Xiangcheng Chu & Wenwu Cao. (2018) Giant Negative Electrocaloric Effect in (Pb,La)(Zr,Sn,Ti)O 3 Antiferroelectrics Near Room Temperature . ACS Applied Materials & Interfaces 10:14, pages 11747-11755.
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Hitoshi Honmi, Yoichiro Hashizume, Takashi Nakajima & Soichiro Okamura. (2017) Thermodynamic analysis of a cooling system using electrocaloric effect. Japanese Journal of Applied Physics 56:10S, pages 10PC09.
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S. Crossley, W. Li, X. Moya & N. D. Mathur. (2016) Large electrocaloric effects in single-crystal ammonium sulfate. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences 374:2074, pages 20150313.
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M. Ožbolt, A. Kitanovski, J. Tušek & A. Poredoš. (2014) Electrocaloric refrigeration: Thermodynamics, state of the art and future perspectives. International Journal of Refrigeration 40, pages 174-188.
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Jani Peräntie, Tatiana Correia, Juha Hagberg & Antti Uusimäki. 2014. Electrocaloric Materials. Electrocaloric Materials 47 89 .
Xinyu Li, Sheng-Guo Lu, Xiang-Zhong Chen, Haiming Gu, Xiao-shi Qian & Q. M. Zhang. (2013) Pyroelectric and electrocaloric materials. J. Mater. Chem. C 1:1, pages 23-37.
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Matjaz Valant. (2012) Electrocaloric materials for future solid-state refrigeration technologies. Progress in Materials Science 57:6, pages 980-1009.
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Y Sarov, S Sainov & V Marinova. (2001) Refractive index of ferroelectric Pb2ScTaO6 single crystals around the phase transition. Materials Science and Engineering: B 83:1-3, pages 231-234.
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Sidney B. Lang & Dilip K. Das-Gupta. 2001. Handbook of Advanced Electronic and Photonic Materials and Devices. Handbook of Advanced Electronic and Photonic Materials and Devices 1 55 .
I. P. Raevskii, V. V. Eremkin, V. G. Smotrakov, E. S. Gagarina & M. A. Malitskaya. (1998) Temperature-composition-degree of compositional ordering phase diagram of lead scandoniobate-scandotantalate solid solutions. Technical Physics Letters 24:12, pages 945-946.
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D.Q Xiao, Y.C Wang, R.L Zhang, S.Q Peng, J.G Zhu & B Yang. (1998) Electrocaloric properties of (1−x)Pb(Mg1/3Nb2/3)O3–xPbTiO3 ferroelectric ceramics near room temperature. Materials Chemistry and Physics 57:2, pages 182-185.
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R. Zhang, S. Peng, D. Xiao, Y. Wang, B. Yang, J. Zhu, P. Yu & W. Zhang. (1998) Preparation and Characterization of (1 —x) Pb(Mg1/3Nb2/3) O3 —x PbTiO3 Electrocaloric Ceramics. Crystal Research and Technology 33:5, pages 827-832.
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D.Q. Xiao, B. Yang, J.G. Zhu & Z.H. Qian. 1994. Ecomaterials. Ecomaterials 605 610 .

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