The cathode catalyst for oxygen reduction reaction is one of the most important factors that can affect the performance of fuel cell.
氧还原反应阴极催化剂对燃料电池的性能起着非常关键的作用。
Recently SRB are found to be able to survive in aerobic conditions. But there is no research on its influence of on oxygen reduction reaction.
近年的研究发现SRB可以生存在有氧条件下,但还没有SRB及其代谢产物对溶解氧还原反应影响的报道。
The origination potential of oxygen reduction reaction being more positive, larger electrolyte concentration and higher temperature could promote the reaction.
增加硫酸电解液浓度,开路电位正移,升高温度有利于反应进行。
The oxygen reduction reaction that takes place at the fuel cell's cathode creates water as its only waste and it is there that up to 40 percent of a fuel cell's efficiency is lost.
对氧还原反应,发生在燃料电池的阴极地方创建作为其唯一的废水和它的存在,多达40燃料电池的效率是百分之丢失。
The results show that: increasing temperature will lead to more methanol to permeate to the cathode, and increase the charge transfer resistance of cathodic oxygen reduction reaction;
只有采用大的空气流量,才会有效地防止水淹,加大氧气向催化剂层的传质,促进阴极反应的进行;
The general substance and oxygen oxidation, the individual may absorb heat, such as the reaction of nitrogen and oxygen. Anodic oxidation and cathodic reduction in electrochemical process.
一般物质与氧气发生氧化时放热,个别可能吸热如氮气与氧气的反应。电化学中阳极发生氧化,阴极发生还原。
Generally, the oxygen reduction and evolution is a two-electron chemical reaction.
讨论了氧还原和氧析出时的电化学反应机理。
Generally, the oxygen reduction and evolution is a two-electron chemical reaction.
讨论了氧还原和氧析出时的电化学反应机理。
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