Feasibility evaluation of low-temperature deposited thin-film electrolyte with successive post-annealing for solid oxide fuel cells
- Authors
- Moon, Minyae; Guha, Puspendu; Oh, Seongkook; Jung, Hangyeol; Yang, Sungeun; Lee, Jong-Ho; Jun, Yongseok; Son, Ji-Won; Kwon, Deok-Hwang
- Issue Date
- 2024-01
- Publisher
- Elsevier BV
- Citation
- Journal of Power Sources, v.589
- Abstract
- During the past decade, thin-film-based solid oxide fuel cells (TF-SOFCs) have demonstrated remarkable performance at a low operating temperature of similar to 500 degrees C by reducing ohmic resistance with vacuum-deposited thin electrolytes. However, a high-temperature deposition process at approximately 700 degrees C is employed in TF-SOFCs, which is only available at a laboratory scale and is not appropriate for commercial deposition equipment. To address this issue, we investigate the feasibility of depositing electrolytes at relatively low temperatures (<= 300 degrees C) accompanied with post-annealing. A TF-SOFC comprising a trilayer thin-film electrolyte, i.e., yttria-stabilized zirconia (YSZ) sandwiched between gadolinia-doped ceria (GDC), fabricated at low-temperature deposition with subsequent post-annealing is selected and tested. Based on a thorough examination using X-ray diffraction and scanning electron microscopy, the appropriate growth conditions for the YSZ and GDC thin-film layers are selected. Through the optimization, we successfully create a low-temperature deposited 750 nm-thick GDC/350 nm-thick YSZ/150 nm-thick GDC (CZC) trilayer electrolyte exhibiting comparable performances with that deposited at 700 degrees C. High performance of a single cell, a peak power density of 890 mW/cm(2) at 500 degrees C, is achieved. This result suggests the potential of fabricating high-quality TF-SOFCs with commercial equipment.
- Keywords
- PERFORMANCE; LAYER; Thin-film SOFC; Electrolyte; GDC/YSZ/GDC; Ionic conductivity; Low-temperature deposition
- ISSN
- 0378-7753
- URI
- https://pubs.kist.re.kr/handle/201004/112963
- DOI
- 10.1016/j.jpowsour.2023.233774
- Appears in Collections:
- KIST Article > 2024
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