Kim Junseok, Im Seunghyeok, Oh Seol Hee, Lee Ji Yeong, Yoon Kyung Joong, Son Ji-Won, Yang Sungeun, Kim Byung-Kook, Lee Jong-Heun, Lee Hae-Weon, Lee Jong-Ho, Ji Ho-Il
Center for Energy Materials Research, Korea Institute of Science and Technology (KIST), Seoul 02792, Republic of Korea.
Department of Materials Science and Engineering, Korea University, Seoul 02841, Republic of Korea.
Sci Adv. 2021 Oct;7(40):eabj8590. doi: 10.1126/sciadv.abj8590. Epub 2021 Oct 1.
Solid oxide cells (SOCs) are promising sustainable and efficient electrochemical energy conversion devices. The application of a bilayer electrolyte comprising wide electrolytic oxide and highly conductive oxide is essential to lower the operating temperatures while maintaining high performance. However, a structurally and chemically ideal bilayer has been unattainable through cost-effective conventional ceramic processes. Here, we describe a strategy of naturally diffused sintering aid allowing the fabrication of defect-free doped-zirconia/doped-ceria bilayer electrolyte with full density and reduced interdiffusion layer at lower sintering temperature owing to the supply of small but appropriate amount of sintering aid from doped zirconia to doped ceria that makes the thermal shrinkages of both layers perfectly congruent. The resulting SOCs exhibit a minimal ohmic loss of 0.09 ohm cm and remarkable performances in both fuel cell (power density exceeding 1.3 W cm) and electrolysis (current density of −1.27 A cm at 1.3 V) operations at 700°C.
固体氧化物电池(SOCs)是很有前景的可持续且高效的电化学能量转换装置。应用包含宽电解氧化物和高导电氧化物的双层电解质对于降低工作温度同时保持高性能至关重要。然而,通过具有成本效益的传统陶瓷工艺无法获得结构和化学上理想的双层。在此,我们描述了一种自然扩散烧结助剂的策略,该策略允许制造无缺陷的掺杂氧化锆/掺杂氧化铈双层电解质,由于从掺杂氧化锆向掺杂氧化铈供应少量但适量的烧结助剂,使得两层的热收缩完全一致,从而在较低烧结温度下具有全密度且互扩散层减少。所得的固体氧化物电池在700°C下表现出最小欧姆损耗为0.09欧姆·厘米,并且在燃料电池(功率密度超过1.3瓦/平方厘米)和电解(在1.3伏时电流密度为-1.27安/平方厘米)操作中均具有出色性能。
