Synthesis and characterization of Ti0.9Ir0.1O2-activated carbon composite as a promising support for catalysts in electrochemical energy conversion

IF 1.7 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
H. T. Pham, Hau Quoc Pham, Q. Huynh, Thao Ngoc Nguyen, N. Huynh, Thanh-Quang Nguyen, T. Huynh
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Abstract

Constructing robust support plays a key role in governing the overall catalytic efficiency of metal-based catalysts for electrochemical reactions in sustainable energy-related conversion systems. We herein use a solvothermal method to assemble Ti0.9Ir0.1O2-Activated C composites, exhibiting high surface area and electrical conductivity compared to the pure TiO2 material. The material characterisations and electrochemical behaviours of the as-obtained composites are systemically studied by XRD, FE-SEM-EDX mapping, FT-IR, XPS, BET, four-point technique, cyclic voltammetry, etc Notably, the effect of composition on the physical and electrochemical properties of the as-made composites is also explored, which indicated the significant improvement in surface area and electrical conductivity with increasing carbon content, while a reverse trend is observed in the electrochemical durability. Among all studied composites, the Ti0.9Ir0.1O2-Activated C (50:50 wt%) composite can be a suitable support for metal-based catalysts due to its balance in physical properties (electrical conductivity of 1.5 S cm−1 and surface area of 152.12 m2 g−1) and electrochemical corrosion resistance (high durability after 2000-cycling ADT). This study can open up an efficient strategy to enhance the catalytic performance of electrochemical processes.
电化学能量转换催化剂载体Ti0.9Ir0.1O2活性炭复合材料的合成与表征
在可持续能源相关转化系统中,构建坚固的支撑体在控制金属基催化剂对电化学反应的整体催化效率方面发挥着关键作用。本文中,我们使用溶剂热法组装Ti0.9Ir0.1O2-活化的C复合材料,与纯TiO2材料相比,其表现出高的表面积和电导率。通过XRD、FE-SEM-EDX图谱、FT-IR、XPS、BET、四点法、循环伏安法等对所制备的复合材料的材料表征和电化学行为进行了系统研究。值得注意的是,还探讨了组成对所制复合材料物理和电化学性能的影响,这表明随着碳含量的增加,表面积和电导率显著提高,而电化学耐久性呈相反趋势。在所有研究的复合材料中,Ti0.9Ir0.1O2-活化的C(50:50wt%)复合材料可以作为金属基催化剂的合适载体,因为它在物理性能(电导率为1.5S cm−1,表面积为152.12 m2 g−1)和电化学耐腐蚀性(2000循环ADT后的高耐久性)方面保持平衡。这项研究可以为提高电化学过程的催化性能开辟一种有效的策略。
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来源期刊
Advances in Natural Sciences: Nanoscience and Nanotechnology
Advances in Natural Sciences: Nanoscience and Nanotechnology NANOSCIENCE & NANOTECHNOLOGYMATERIALS SCIE-MATERIALS SCIENCE, MULTIDISCIPLINARY
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