Torigoe Kanjiro, Takahashi Masatoshi, Tsuchiya Koji, Iwabata Kazuki, Ichihashi Toshinari, Sakaguchi Kengo, Sugawara Fumio, Abe Masahiko
Acteiive Co. Ltd., 2641 Yamazaki, Noda 278-8510, Japan.
Department of Pure and Applied Chemistry, Research Institute for Science and Technology, Research Equipment Center, and Department of Applied Biological Science, Tokyo University of Science, 2641 Yamazaki, Noda 278-8510, Japan.
ACS Omega. 2018 Dec 26;3(12):18323-18333. doi: 10.1021/acsomega.8b02739. eCollection 2018 Dec 31.
We developed a high-power abiotic direct glucose fuel cell system using a Au-Pt bimetallic anode catalyst. The high power generation (95.7 mW cm) was attained by optimizing operating conditions such as the composition of a bimetallic anode catalyst, loading amount of the metal catalyst on a carbon support, ionomer/carbon weight ratio when the catalyst was applied to the anode, glucose and KOH concentrations in the fuel solution, and operating temperature and flow rate of the fuel solution. It was found that poly(-vinyl-2-pyrrolidone)-stabilized AuPt nanoparticles (mean diameter 1.5 nm) on a carbon (Ketjen Black 600) support function as a highly active anode catalyst for the glucose electrooxidation. The ionomer/carbon weight ratio also greatly affects the cell properties, which was found to be optimal at 0.2. As for the glucose concentration, a maximum cell power was derived at 0.4-0.6 mol dm. A high KOH concentration (4.0 mol dm) was preferable for deriving the maximum power. The cell power increased with the increasing flow rate of the glucose solution up to 50 cm min and leveled off thereafter. At the optimal condition, the maximum power density and corresponding cell voltage of 58.2 mW cm (0.36 V) and 95.7 mW cm (0.34 V) were recorded at 298 and 328 K, respectively.
我们开发了一种使用金 - 铂双金属阳极催化剂的高功率非生物直接葡萄糖燃料电池系统。通过优化操作条件,如双金属阳极催化剂的组成、金属催化剂在碳载体上的负载量、将催化剂应用于阳极时的离聚物/碳重量比、燃料溶液中的葡萄糖和氢氧化钾浓度以及燃料溶液的操作温度和流速,实现了高发电功率(95.7毫瓦/平方厘米)。研究发现,在碳(科琴黑600)载体上由聚乙烯基 - 2 - 吡咯烷酮稳定的金铂纳米颗粒(平均直径1.5纳米)作为葡萄糖电氧化的高活性阳极催化剂。离聚物/碳重量比也对电池性能有很大影响,发现其在0.2时最佳。至于葡萄糖浓度,在0.4 - 0.6摩尔/立方分米时可获得最大电池功率。高氢氧化钾浓度(4.0摩尔/立方分米)有利于获得最大功率。电池功率随着葡萄糖溶液流速增加到50立方厘米/分钟而增加,此后趋于平稳。在最佳条件下,在298和328K时分别记录到最大功率密度和相应的电池电压为58.2毫瓦/平方厘米(0.36伏)和95.7毫瓦/平方厘米(0.34伏)。
