Anode Catalysts in CO2 Electrolysis: Challenges and Untapped Opportunities.

The field of electrochemical carbon dioxide reduction has developed rapidly during recent years. At the same time, the role of the anodic half-reaction has received considerably less attention. In this Perspective, we scrutinize the reports on the best-performing CO2 electrolyzer cells from the past 5 years, to shed light on the role of the anodic oxygen evolution catalyst. We analyze how different cell architectures provide different local chemical environments at the anode surface, which in turn determines the pool of applicable anode catalysts. We uncover the factors that led to either a strikingly high current density operation or an exceptionally long lifetime. On the basis of our analysis, we provide a set of criteria that have to be fulfilled by an anode catalyst to achieve high performance. Finally, we provide an outlook on using alternative anode reactions (alcohol oxidation is discussed as an example), resulting in high-value products and higher energy efficiency for the overall process.

Local Chemical Environment Governs Anode Processes in CO2 Electrolyzers.

A major goal within the CO2 electrolysis community is to replace the generally used Ir anode catalyst with a more abundant material, which is stable and active for water oxidation under process conditions. Ni is widely applied in alkaline water electrolysis, and it has been considered as a potential anode catalyst in CO2 electrolysis. Here we compare the operation of electrolyzer cells with Ir and Ni anodes and demonstrate that, while Ir is stable under process conditions, the degradation of Ni leads to a rapid cell failure. This is caused by two parallel mechanisms: (i) a pH decrease of the anolyte to a near neutral value and (ii) the local chemical environment developing at the anode (i.e., high carbonate concentration). The latter is detrimental for zero-gap electrolyzer cells only, but the first mechanism is universal, occurring in any kind of CO2 electrolyzer after prolonged operation with recirculated anolyte.

[Malaria in Hungary: origin, current state and principles of prevention]. / A maláriakérdés Magyarországon: elózmények, aktuális állapot és védekezési elvek.

Malaria was an endemic disease in Hungary for many centuries. A country-wide survey of the epidemiologic situation on malaria started in the year of 1927. That was done by the Department of Parasitology of the Royal State Institute of Hygiene (presently: Johan Béla National Center for Epidemiology). The notification of malaria was made compulsory in 1930. Free of charge laboratory examination of the blood of persons suffering from malaria or suspected of an infection have been carried out. Anti-malarial drugs were also distributed free of charge, together with appropriate medical advise given at the anti-malarial sanitary stations. Between 1933 and 1943, the actual number of malaria cases was estimated as high as 10-100,000 per year. The major breakthrough came in 1949 by the organized antimalarial campaign applying DDT for mosquito eradication. The drastic reduction of the vectors resulted in the rapid decline of malaria cases. Since 1956, there have not been reported any indigenous case in Hungary. In 1963, Hungary entered on the Official Register of the WHO to the areas where malaria eradication has been achieved. During the period of 1963-2001, 169 Hungarians acquired the malaria in abroad and 263 foreigners infected in abroad were registered in Hungary. More than half of the cases (230) were caused by Plasmodium falciparum. Further 178 cases were caused by Plasmodium vivax and 24 cases by other Plasmodium species. During that period, 7 fatal cases were reported (Plasmodium falciparum). The expansion of migration (both the increase of the number of foreigners travelling into Hungary and of Hungarians travelling abroad) favours to the appearance of imported cases. Attention is called of all the persons travelling to malaria endemic countries to the importance of malaria prevention by the International Vaccination Stations located in the National Center for Epidemiology and in the Public Health Institutes of 19 counties and of Budapest. The Johan Béla National Center for Epidemiology issued a protocol in 2001, the title of which is: "Antimalarial defence". This helps the information activity of the International Vaccination Stations. To prevent malaria infections, systemic mosquito eradication is organized and supervised by the Office of the Chief Medical Officer at the touristically important areas in the summer season.