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20.07.2020 | Ceramics

[(Bi_0.50Na_0.40K_0.10)_0.94Ba_0.06]_1-xLa_xTi_0.975Ta_0.025O₃ lead-free relaxor ceramics with high energy storage density and thermally stable dielectric properties

verfasst von: Benben Yan, Huiqing Fan, Arun Kumar Yadav, Chao Wang, Zhinan Du, Mengyuan Li, Weijia Wang, Wenqiang Dong, Shuren Wang

Erschienen in: Journal of Materials Science | Ausgabe 30/2020

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Abstract

Dielectric ceramics for capacitors have attained significant attention in current time owing to their large power densities and fast charge/discharge rates. Lead-free [(Bi_0.50Na_0.40K_0.10)_0.94Ba_0.06]_1-xLa_xTi_0.975Ta_0.025O₃ (abbreviated as BNKBTT-100xLa) relaxor ceramics are prepared using mixed-oxide technique. All ceramics are revealed a pseudo-cubic structure using X-ray diffraction technique. The long-range order existing in BNKBTT-100xLa ceramics is found to reduce with increasing composition. As a result, a highly effective energy storage density (W_rec) ~ 1.558 J/cm³ and efficiency (η) ~ 88.46% is achieved in BNKBTT-2La ceramic. In addition, BNKBTT-2La composition is fatigue-free up to 10⁵ cycles. Also, BNKBTT-4La ceramic exhibits a dielectric constant (ε') ~ 2281 near 150 °C with Δε'/ε'_150 °C below 15% over a large range from 39 to 383 °C, showing an outstanding dielectric temperature stability. Therefore, BNKBTT-2La and BNKBTT-4La ceramics are outstanding for energy density and thermally stable dielectric permittivity, respectively, for the device applications.

Vorheriger Artikel Control of stoichiometry and morphology in polycrystalline V2O3 thin films using oxygen buffers

Nächster Artikel Reconfigurable and tunable photo-controlled hydrogel using hydrogen bonding to drive molecule self-assembly and cross-linking

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Titel: [(Bi0.50Na0.40K0.10)0.94Ba0.06]1-xLaxTi0.975Ta0.025O3 lead-free relaxor ceramics with high energy storage density and thermally stable dielectric properties
verfasst von: Benben Yan
Huiqing Fan
Arun Kumar Yadav
Chao Wang
Zhinan Du
Mengyuan Li
Weijia Wang
Wenqiang Dong
Shuren Wang
Publikationsdatum: 20.07.2020
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 30/2020
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-020-05070-y

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