Jiaming Yang, Yueyue Sun, Lei Fu, Zhengrong Liu, Jun Zhou, Kai Wu
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A-site deficiency played a critical role in Ni exsolution and the morphology of LSTNx nanofibers. La 0.4 Sr 0.4 Ti 0.9 Ni 0.1 O 3-δ fibers with moderate A-site deficiency displayed homogeneous Ni NPs on the surface and excellent stability at 800℃ in pure H 2 . A single cell with LSTN0.4 fuel electrode (~40 μm) | GDC barrier layer (~0.5 μm) | SSZ electrolyte (~250 μm) | GDC barrier layer (~0.5 μm) | composite LSCF-GDC air electrode (~40 μm) exhibits maximum power density of 547.44 mW·cm -2 at 800℃ in wet H 2 and the current density of -1.351 A·cm -2 under the potential of 1.5 V in 50% H 2 O/H 2 atmosphere. The 5-cyclic long-term reversible tests of FC and EC modes were carried out under the potential of 0.5/1.5 V for 60 h, respectively. The current density degradation was approximately 0.67% in EC mode and 2.73% in FC mode after 5-cyclic reversible tests in LSTN0.4 single cells, suggesting a reliable fiber-structured architecture for RSOCs. 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Here, we demonstrate an advanced fiber-structured La x Sr x Ti 0.9 Ni 0.1 O 3-δ (LSTNx) architecture with a series of A-site deficiency (x=0.5, 0.45, and 0.4), which can be applied to reversible solid cells as a promising candidate of fuel electrode materials. LSTNx fibers decorated with Ni nanoparticles (NPs) were fabricated via electrospinning technique and in-situ exsolution method. A-site deficiency played a critical role in Ni exsolution and the morphology of LSTNx nanofibers. La 0.4 Sr 0.4 Ti 0.9 Ni 0.1 O 3-δ fibers with moderate A-site deficiency displayed homogeneous Ni NPs on the surface and excellent stability at 800℃ in pure H 2 . A single cell with LSTN0.4 fuel electrode (~40 μm) | GDC barrier layer (~0.5 μm) | SSZ electrolyte (~250 μm) | GDC barrier layer (~0.5 μm) | composite LSCF-GDC air electrode (~40 μm) exhibits maximum power density of 547.44 mW·cm -2 at 800℃ in wet H 2 and the current density of -1.351 A·cm -2 under the potential of 1.5 V in 50% H 2 O/H 2 atmosphere. The 5-cyclic long-term reversible tests of FC and EC modes were carried out under the potential of 0.5/1.5 V for 60 h, respectively. The current density degradation was approximately 0.67% in EC mode and 2.73% in FC mode after 5-cyclic reversible tests in LSTN0.4 single cells, suggesting a reliable fiber-structured architecture for RSOCs. 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引用次数: 0
摘要
可逆固体氧化物电池(rsoc)作为一种新型的能量转换器件,具有优异的转换效率,可以在燃料电池(FC)模式和电解电池(EC)模式下工作。然而,由于氢催化动力学缓慢,燃料电极材料的主要挑战是电化学性能差和耐用性有限。在这里,我们展示了一种先进的纤维结构La x Sr x Ti 0.9 Ni 0.1 O 3-δ (LSTNx)结构,具有一系列a位缺陷(x=0.5, 0.45和0.4),可以应用于可逆固体电池,作为有希望的候选燃料电极材料。采用静电纺丝技术和原位溶出法制备了镍纳米粒子修饰的LSTNx纤维。a位缺失对镍的析出和LSTNx纳米纤维的形貌起关键作用。中等a位缺陷的La 0.4 Sr 0.4 Ti 0.9 Ni 0.1 O 3-δ纤维在表面表现出均匀的Ni NPs,在800℃纯h2中具有优异的稳定性。采用LSTN0.4燃料电极(~40 μm)、| GDC阻挡层(~0.5 μm)、| SSZ电解质(~250 μm)、| GDC阻挡层(~0.5 μm)、|复合LSCF-GDC空气电极(~40 μm)的单电池在800℃湿h2条件下的最大功率密度为547.44 mW·cm -2,在50% h2o / h2气氛下1.5 V电位下的电流密度为-1.351 A·cm -2。在0.5/1.5 V电势下分别进行FC和EC模式的5循环长期可逆试验,持续60 h。在LSTN0.4单细胞中进行5循环可逆测试后,在EC模式下电流密度下降约0.67%,在FC模式下电流密度下降约2.73%,表明rsoc具有可靠的纤维结构结构。图1
A-Site Deficient Lst-Based Perovskite Fibers with Ni Exsolution for Reversible Solid Oxide Cells
Reversible solid oxide cells (RSOCs) as new energy converting devices with superior conversion efficiency can operate in both fuel cell (FC) mode and electrolysis cell (EC) mode. However, the main challenges for fuel electrode materials are poor electrochemical performance and limited durability due to the sluggish hydrogen catalysis kinetics. Here, we demonstrate an advanced fiber-structured La x Sr x Ti 0.9 Ni 0.1 O 3-δ (LSTNx) architecture with a series of A-site deficiency (x=0.5, 0.45, and 0.4), which can be applied to reversible solid cells as a promising candidate of fuel electrode materials. LSTNx fibers decorated with Ni nanoparticles (NPs) were fabricated via electrospinning technique and in-situ exsolution method. A-site deficiency played a critical role in Ni exsolution and the morphology of LSTNx nanofibers. La 0.4 Sr 0.4 Ti 0.9 Ni 0.1 O 3-δ fibers with moderate A-site deficiency displayed homogeneous Ni NPs on the surface and excellent stability at 800℃ in pure H 2 . A single cell with LSTN0.4 fuel electrode (~40 μm) | GDC barrier layer (~0.5 μm) | SSZ electrolyte (~250 μm) | GDC barrier layer (~0.5 μm) | composite LSCF-GDC air electrode (~40 μm) exhibits maximum power density of 547.44 mW·cm -2 at 800℃ in wet H 2 and the current density of -1.351 A·cm -2 under the potential of 1.5 V in 50% H 2 O/H 2 atmosphere. The 5-cyclic long-term reversible tests of FC and EC modes were carried out under the potential of 0.5/1.5 V for 60 h, respectively. The current density degradation was approximately 0.67% in EC mode and 2.73% in FC mode after 5-cyclic reversible tests in LSTN0.4 single cells, suggesting a reliable fiber-structured architecture for RSOCs. Figure 1
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