BaCe0.7-xZr0.1FexY0.1Yb0.1功能層應用於高效能質子型固態氧化物電化學電池之研究;BaCe0.7-xZr0.1FexY0.1Yb0.1 Functional Layers for High-Performance Protonic Solid Oxide Electrochemical Cells

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Please use this identifier to cite or link to this item: https://ir.lib.ncu.edu.tw/handle/987654321/97723

Title:	BaCe0.7-xZr0.1FexY0.1Yb0.1功能層應用於高效能質子型固態氧化物電化學電池之研究;BaCe0.7-xZr0.1FexY0.1Yb0.1 Functional Layers for High-Performance Protonic Solid Oxide Electrochemical Cells
Authors:	陳宇弘;Yu-Hong
Contributors:	材料科學與工程研究所
Keywords:	可逆固態氧化物電池;燃料電池;電解電池;空氣電極功能層;PBSCF;Reversible Solid Oxide Cells (R-SOC);fuel cells;electrolysis cells;interlayer;PBSCF
Date:	2025-08-28
Issue Date:	2025-10-17 11:50:10 (UTC+8)
Publisher:	國立中央大學
Abstract:	本研究旨在利用固態反應合成法，將鐵(Fe)摻雜至 BaCe0.7Zr0.1Y0.1Yb0.1O3-δ 中，以優化質子導電型固態氧化物電池(Proton-conducting solid oxide cell, P-SOC)空氣電極功能層的電化學性能。鐵摻雜作為一種受體型摻雜機制，透過低價態 Fe³⁺ 部分取代高價態 Ce⁴⁺，不僅促進氧空位的生成，亦藉由電荷補償效應引入電子電洞(h⁺)，從而進一步提升材料的電子導電性與催化活性，形成穩定的混合離子電子導體結構。基於此機制，預期經摻雜改質後的 BaCe0.7-xZr0.1FexY0.1Yb0.1 空氣電極功能層，能顯著增強固態氧化物電池的電化學表現。實驗結果顯示，未經改質的空氣電極功能層在 650 °C 操作溫度下，其燃料電池峰值功率密度達 1064 mW cm⁻²；在相同溫度下進行電解模式測試時，於 1.6 V 下的電解電流密度可達 2364 mA cm⁻²，展現出優異的能量轉換效率與電流輸出能力。經鐵摻雜改質後，空氣電極功能層在 650 °C 下的燃料電池峰值功率密度提升至 1345 mW cm⁻²；於相同條件下的電解模式測試中，在 1.6 V 下的電解電流密度進一步提高至 4732 mA cm⁻²，證實摻雜改質顯著促進了電池性能。 ;This study aims to enhance the electrochemical performance of the air electrode functional layer in a proton-conducting solid oxide cell (P-SOC) by incorporating iron (Fe) into BaCe0.7Zr0.1Y0.1Yb0.1O3-δ via a solid-state reaction method. Fe acts as an acceptor dopant by partially substituting low-valence Fe3+ for high-valence Ce4+, which not only promotes the formation of oxygen vacancies but also introduces electronic holes (h+) through a charge compensation mechanism. These effects collectively improve the electronic conductivity and catalytic activity of the material, forming a stable mixed ionic-electronic conducting structure. Based on this mechanism, the Fe-doped BaCe0.7-xZr0.1FexY0.1Yb0.1 air electrode functional layer is expected to significantly improve the electrochemical performance of the solid oxide cell. Experimental results show that the undoped air electrode functional layer achieved a peak power density of 1064 mW cm-2 at an operating temperature of 650 °C in fuel cell mode, and an electrolysis current density of 2364 mA cm-2 at 1.6 V under the same temperature in electrolysis mode, demonstrating excellent energy conversion efficiency and current output. After Fe doping, the peak power density at 650 °C increased to 1345 mW cm-2, while the electrolysis current density at 1.6 V further increased to 4732 mA cm-2 under identical conditions, confirming that Fe doping significantly enhances the overall performance of the cell.
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