重新设计质子陶瓷电化学电池以降低工作温度。

Redesigning protonic ceramic electrochemical cells to lower the operating temperature.

作者信息

Liu Fan, Diercks David, Kumar Praveen, Seong Arim, Jabbar Mohammed Hussain Abdul, Gumeci Cenk, Furuya Yoshihisa, Dale Nilesh, Oku Takanori, Usuda Masahiro, Kazempoor Pejman, Ghamarian Iman, Liu Lin, Fang Liyang, Chen Di, Wang Zixian, Skinner Stephen, Duan Chuancheng

机构信息

Department of Chemical Engineering, Kansas State University, Manhattan, KS, USA.

Shared Instrumentation Facility, Colorado School of Mines, Golden, CO, USA.

出版信息

Sci Adv. 2025 Jan 10;11(2):eadq2507. doi: 10.1126/sciadv.adq2507.

DOI:10.1126/sciadv.adq2507

PMID:39792665

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11721582/

Abstract

Protonic ceramic electrochemical cells (PCECs) can operate at intermediate temperatures (450° to 600°C) for power generation and hydrogen production. However, the operating temperature is still too high to revolutionize ceramic electrochemical cell technology. Lowering the operating temperature to <450°C will enable a wider material choice and reduce system costs. We present approaches to redesigning PCECs via readily fabricated single-grain-thick, chemically homogeneous, and robust electrolytes and a nano-micro positive electrode. At 450°C, the PCECs achieve a peak power density of 1.6 watt per square centimeter on H fuel, 0.5 watt per square centimeter on NH fuel, and 0.3 watt per square centimeter on CH fuel in fuel cell mode. In steam electrolysis mode, a current density of >0.6 ampere per square centimeter with a Faradaic efficiency of >90% is achievable at 1.4 volt and 400°C. In addition, exceptional durability (>2000 hours) has been demonstrated, with a degradation rate of <0.01 millivolt per 100 hours in fuel cell mode at 400°C.

摘要

质子陶瓷电化学电池（PCEC）可在中温（450°至600°C）下运行以进行发电和制氢。然而，其运行温度仍然过高，无法彻底变革陶瓷电化学电池技术。将运行温度降低至<450°C将能提供更广泛的材料选择并降低系统成本。我们提出了通过易于制造的单晶粒厚、化学均匀且坚固的电解质以及纳米-微米级正极来重新设计PCEC的方法。在450°C下，PCEC在燃料电池模式下，以氢气为燃料时峰值功率密度达到每平方厘米1.6瓦，以氨气为燃料时为每平方厘米0.5瓦，以甲烷为燃料时为每平方厘米0.3瓦。在蒸汽电解模式下，在1.4伏和400°C时可实现每平方厘米>0.6安培的电流密度，法拉第效率>90%。此外，已证明其具有出色的耐久性（>2000小时），在400°C的燃料电池模式下，降解速率<每100小时0.01毫伏。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/b287/11721582/d5bd2f824f4d/sciadv.adq2507-f1.jpg

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重新设计质子陶瓷电化学电池以降低工作温度。

Redesigning protonic ceramic electrochemical cells to lower the operating temperature.

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