Pusan National University Study Provides Breakthrough in Enhancing Solid Oxide Fuel Cell Efficiency With Rapid PrOx Coating Method
Pusan National University Study Provides Breakthrough in Enhancing Solid Oxide Fuel Cell Efficiency With Rapid PrOx Coating Method
Rapid electrochemical method enhances solid oxide fuel cell electrodes, reducing polarization resistance and boosting peak power density
快速電化學方法增強了固體氧化物燃料電池的電極,降低了極化電阻並提高了峯值功率密度。
BUSAN, South Korea, July 19, 2024 /PRNewswire/ -- Improving the efficiency of solid oxide fuel cells (SOFCs) is crucial for advancing clean energy technologies. Researchers from Korea have developed a rapid, practical method to deposit a praseodymium oxide (PrOx) layer on lanthanum strontium manganite–yttria-stabilized zirconia (LSM–YSZ) composite electrodes. This PrOx coating significantly enhances oxygen reduction and boosts electrode performance, reducing polarization resistance by 89% and increasing reliability and efficiency in energy production.
韓國釜山,2024年7月19日/美通社/--提高固體氧化物燃料電池(SOFCs)效率對於推進清潔能源技術至關重要。來自韓國的研究人員發現了一種快速實用的方法,使用陰極電化學沉積將一層氧化鐠(PrOx)沉積在鑭釔錳酸鹽-穩定氧化鋯(LSM-YSZ)複合電極上。這種PrOx塗層顯着提高了氧還原反應,並提高了電極性能,將極化電阻降低了89%,提高了能量產生的可靠性和效率。
Rising global demand for clean energy drives advancements in technologies like SOFCs, known for converting hydrogen and methane into emission-free electricity. SOFCs rely on key components: electrodes (cathode and anode) and the electrolyte, which are essential for converting chemical energy into electrical energy. These components are typically made from materials like lanthanum strontium manganite (LSM) and yttria-stabilized zirconia (YSZ). Combining LSM and YSZ to form LSM-YSZ enhances stability and durability, ensuring a prolonged electrode lifespan.
全球對清潔能源的需求增長驅動了像固體氧化物燃料電池(SOFC)這樣轉化氫和甲烷爲無排放電力的技術的進步。SOFC依賴於關鍵部件:電極(陰極和陽極)和電解液,它們對於將化學能轉化爲電能至關重要。這些部件通常由諸如鑭釔錳酸鹽(LSM)和穩定氧化鋯(YSZ)等材料製成。將LSm和YSZ組合形成LSm-YSZ可以增強穩定性和耐久性,確保電極壽命更長。
Current SOFC technology faces challenges, notably electrode degradation, exacerbated at lower temperatures. Enhancing the oxygen reduction reaction (ORR) at the cathode is crucial for improving ion flow and overall fuel cell performance and durability. Addressing these issues is vital for expanding SOFC applications in energy conversion systems.
當前的SOFC技術面臨挑戰,尤其是在低溫下,電極退化加劇。提高陰極中的氧還原反應(ORR)對於改進離子流和整體燃料電池的性能和耐久性至關重要。解決這些問題對於擴展SOFC在能源轉換系統中的應用至關重要。
To address current challenges, a team of researchers led by Professor Beom-Kyeong Park recently conducted a study aimed at enhancing the performance of LSM–YSZ electrodes in SOFCs. Their research, available online since March 22, 2024, and published in Volume 36 of the Journal of Advanced Materials on June 20, 2024, focused on improving LSM–YSZ electrodes using nanocatalysts such as praseodymium oxide (PrOx). These catalysts, known for their high surface area-to-volume ratios, were employed to enhance the efficiency of the ORR.
爲了應對當前的挑戰,由樸範京教授領導的研究團隊最近進行了一項研究,旨在改善SOFC中LSM-YSZ電極的性能。他們的研究可自2024年3月22日起在網上查詢,並於2024年6月20日在《先進材料》第36捲上發表,重點是使用釹氧化物(PrOx)等納米催化劑改進LSM-YSZ電極。這些催化劑以高比表面積與體積比而聞名,可用於增強ORR的效率。
Using cathodic electrochemical deposition (CELD), the research team efficiently deposited PrOx nanocatalysts onto LSM-YSZ electrodes in less than four minutes without requiring heat treatment. Prof. Park highlighted the significance, stating, "We harness the outstanding catalytic properties of PrOx to notably enhance the ORR activity of LSM–YSZ electrodes. The CELD method provides a rapid and cost-effective solution, feasible under standard operating conditions."
使用陰極電化學沉積(CELD),研究團隊在不需要熱處理的情況下,在不到四分鐘的時間內高效沉積PrOx納米催化劑於LSm-YSZ電極上。樸教授強調了其顯着性,稱"我們利用PrOx的卓越催化性能顯著增強了LSM-YSZ電極的ORR活性。CELD方法提供了一種快速和經濟的解決方案,可在標準操作條件下實現。"
The study demonstrated significant enhancements in SOFC electrode performance with PrOx coating, showing an 89% resistance reduction at high temperatures sustained over 400 hours. Achieving 418 mW cm−2 peak power density at 650°C surpassed other cathodes. Research also explored (Pr,Ce)Ox multicomponent coatings via electrochemical deposition, offering avenues for further optimization.
該研究表明,在使用PrOx塗層的SOFC電極中顯着提高了性能,在高溫下持續了400小時以上,極化阻力降低了89%。在650°C時達到418 mW cm−2的峯值功率密度超過了其他陰極。研究還探討了(Pr,Ce)Ox多組分塗層的電化學沉積,爲進一步優化提供了途徑。
Prof. Park emphasizes the far-reaching implications of their research, stating, "By significantly enhancing electrode performance and durability, our method could pave the way for wider adoption of SOFCs in energy conversion and storage systems. This advancement holds immense promise for applications requiring reliable and sustainable power generation. It offers a pathway to mitigate greenhouse gas emissions and enhance global energy security."
樸教授強調了他們研究的深遠影響,稱"通過顯著提高電極性能和耐久性,我們的方法可能爲SOFC在能源轉換和儲存系統中的更廣泛應用鋪平道路。這一進步在需要可靠和可持續的發電的應用中有着巨大的潛力,可以爲減輕溫室氣體排放和增強全球能源安全提供一種途徑。"
This innovative approach to creating high-performance energy devices, including all-ceramic materials, presents a promising future for clean energy technology.
利用這種創新方法來創建高性能能源設備,包括全陶瓷材料,爲清潔能源技術帶來了有前途的未來。
Reference
來源Sengenics
Title of original paper: Revitalizing Oxygen Reduction Reactivity of Composite Oxide Electrodes via Electrochemically Deposited PrOx Nanocatalysts
原論文標題:通過電化學沉積的PrOx納米催化劑爲複合氧化物電極注入新生
Journal: Advanced materials
期刊:《先進材料》
DOI:
DOI:
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