Waste Water Treatment in Direct Borohydride Fuel Cell with Bipolar Membrane

It was established that application of bipolar membrane in a direct borohydride fuel cell (DBFC) with H2O2 co-generation enabled to keep constant pH in catholyte within 2.5 - 3.2 limits, which allowed us to carry out treatment of water polluted by organic compounds in fuel cell catholyte. Treatment of water was carried out by electro-Fenton and photo-electro-Fenton methods. With the view of efficiency, photo-electro-Fenton method of treatment was the most efficient, which enabled to decrease COD of catholytes containing (in each case) phenol, valsaren, 400 g/L dymethoate (BI-58) and valsaciper from 500 ppm to 30, 11, 9 and 3 ppm, respectively after 180 min treatment. By increasing the catholyte temperature from 20℃?to 40℃?in the same period, phenol COD fell to 5 ppm.

AuPd/C作为直接NaBH_4-H_2O_2燃料电池阳极催化剂的性能

采用浸渍还原法制备不同比例的AuPd/C纳米粒子;分别采用X线衍射仪(XRD)和透射电镜(TEM)对催化剂进行结构和形貌分析;利用CHI660a电化学工作站对催化剂进行电化学测试,结果表明:催化剂材料均为面心立方结构,AuPd/C中纳米合金粒子的粒径为5 nm左右,比Au/C中的纳米Au粒子更小,且均匀分散在VXC-72R炭黑的表面;Au/C的峰电流密度为25.05 mA/cm2,与Au/C相比,AuPd/C明显提高NaBH4的电氧化催化活性;以纳米AuPd/C为阳极催化剂、Au/C为阴极催化剂制成直接NaBH4-H2O2燃料电池(DBHFC),发现以Au1Pd2/C为阳极催化剂的DBHFC拥有良好的电池性能;在温度为60℃、NaBH4浓度为1 mol/L时DBHFC的最大功率密度达到114.6 mW/cm2。

纳米Au粒子作为直接硼氢化钠-过氧化氢燃料电池阴极催化剂

采用浸渍还原法制备了纳米Au/C,并将其用作直接硼氢化钠-过氧化氢燃料电池阴极催化剂.通过X射线衍射(XRD)和透射电镜(TEM)对催化剂进行结构和形貌分析,结果表明10～20nm的纳米Au粒子均匀地分散在VulcanXC-72R碳黑表面上.循环伏安测试表明,在0.5mol·L-1H2SO4和2mol·L-1H2O2混合溶液中,纳米Au/C在0.85V处表现较强的不可逆还原电流.以纳米Au/C为阴极催化剂,AB5储氢合金为阳极催化剂制成直接硼氢化钠-过氧化氢燃料电池.电池在30℃下的最大功率密度可达到78.6mW·cm-2.当电池工作温度升高至50℃时,电池的最大功率密度超过120mW·cm-2.此外,研究了阴极溶液中H2SO4和H2O2浓度对电池性能的影响.当阴极溶液中H2SO4浓度小于0.5mol·L-1时,酸浓度对电池性能影响较大;H2O2浓度对电池性能影响较小.确定了阴极溶液中H2SO4和H2O2的最佳浓度分别为0.5和2mol·L-1.