期刊
JOURNAL OF MATERIALS CHEMISTRY C
卷 8, 期 38, 页码 13306-13318出版社
ROYAL SOC CHEMISTRY
DOI: 10.1039/d0tc03505j
关键词
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资金
- Natural Science Foundation of China [51602243, 51911530125]
- China Postdoctoral Science Foundation [2019M663697]
- 111 Project of China [B14040]
- U.S. Office of Naval Research [N00014-16-1-3106]
- Natural Sciences and Engineering Research Council of Canada (NSERC) [RGPIN-2017-06915]
- China Scholarship Council (CSC)
The coexistence of relaxor ferroelectric behaviour and ferromagnetic ordering in a single-phase material is of both fundamental interest and practical potential for applications. To study this rather unusual phenomenon, a series of multiferroic solid solutions of (1 -x)Pb(Fe0.5Nb0.5)O-3-xBiFeO(3)(PFN-BFO, with 0 <= x <= 0.6) were synthesized in the form of ceramics using the solid-state reaction technique and its relaxor and magnetic properties were systematically characterized in this work. Structural refinements based on X-ray diffraction data at room temperature reveal the phase evolution from a monoclinic phase withCmsymmetry to a pseudo-cubic phase withPm3msymmetry with increasing BFO content. The ferroelectric phase transition and relaxor behaviour were investigatedviavariable-temperature dielectric spectroscopy. A temperature-composition phase diagram was constructed in terms ofT(C),T-m, the Burns temperature (T-B) and freezing temperature (T-f), which delimits a ferroelectric phase (FE) forx< 0.025 atT<= 0.3, and a paraelectric state (PE) aboveT(B)for all the compositions. The differences in the microstructures and electrical properties between this work and those reported in the literature are carefully compared and discussed, which are closely related to the preparation conditions. In addition, the evolution of magnetic ordering with composition and temperature was investigated. A ferromagnetic order is induced by the substitution of a moderate amount of BFO (0.1 <= x <= 0.2), which exists up to room temperature. The complex magnetic phase diagram is established, which delimits an antiferromagnetic state (AFM(1)) forx= 0, two weakly ferromagnetic states, WFM(1)and WFM(2)for 0.1 <= x <= 0.2, another antiferromagnetic state (AFM(2)) for the compositions withx >= 0.25 atT <= T-N, and a paramagnetic phase (PM) for all the compositions atT >= T-N. The coexistence of relaxor behaviour and ferromagnetic ordering at room temperature makes the PFN-BFO solid solution a particularly interesting multiferroic material.
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