Add to ORKGTexto completo:acesso restrito. p. 288-290The effect of FeS and PbS on capacity and self-discharge of an iron porous electrode used in a Fe–Ni battery was investigated. Addition of 1wt.% FeS or 1wt.% PbS promotes a significant increase in capacity and inhibits the self-discharge of the iron electrode. This effect is most significant in the presence of PbS
For iron-air batteries, it has yet to be established which iron-containing material is the best cand...
Alkaline Ni-Fe batteries employ sintered iron electrodes as anodes. Iron oxide and copper powders ar...
It has recently been established that 1-octanethiol in the electrolyte can allow iron-electrodes to ...
AbstractIn this article we use a surface response approach to investigate the effect of iron sulphid...
The effect of FeS, PbS and $Bi_2S_3$ additives on the charge/discharge reactions of porous iron elec...
In this article we use a surface response approach to investigate the effect of iron sulphide as wel...
The discharge capacity of a porous iron electrode is controlled by either the extent of interparticl...
7 figures.-- Supporting information available.Iron–air systems are a very promising technology with ...
We report the fast discharge–charge cycle of micro-sized FePS3 electrode particles in all-solid-stat...
Iron-based aqueous batteries, such as the iron-air and nickel-iron chemistries, are limited by passi...
In order to investigate the role of iron additive in the Ni 3S2 electrode, the Ni3S2 electrode was p...
In order to investigate the role of iron additive in the Ni3S2 electrode, the Ni3S2 electrode was pr...
International audienceFe-based air alkaline batteries are promising candidates for large scale energ...
Pyrite (FeS2) has been regarded as one of the most promising electrode materials for sodium ion batt...
Iron is one of the most abundant elements in the earth’s crust and its applications are myriad; one ...
For iron-air batteries, it has yet to be established which iron-containing material is the best cand...
Alkaline Ni-Fe batteries employ sintered iron electrodes as anodes. Iron oxide and copper powders ar...
It has recently been established that 1-octanethiol in the electrolyte can allow iron-electrodes to ...
AbstractIn this article we use a surface response approach to investigate the effect of iron sulphid...
The effect of FeS, PbS and $Bi_2S_3$ additives on the charge/discharge reactions of porous iron elec...
In this article we use a surface response approach to investigate the effect of iron sulphide as wel...
The discharge capacity of a porous iron electrode is controlled by either the extent of interparticl...
7 figures.-- Supporting information available.Iron–air systems are a very promising technology with ...
We report the fast discharge–charge cycle of micro-sized FePS3 electrode particles in all-solid-stat...
Iron-based aqueous batteries, such as the iron-air and nickel-iron chemistries, are limited by passi...
In order to investigate the role of iron additive in the Ni 3S2 electrode, the Ni3S2 electrode was p...
In order to investigate the role of iron additive in the Ni3S2 electrode, the Ni3S2 electrode was pr...
International audienceFe-based air alkaline batteries are promising candidates for large scale energ...
Pyrite (FeS2) has been regarded as one of the most promising electrode materials for sodium ion batt...
Iron is one of the most abundant elements in the earth’s crust and its applications are myriad; one ...
For iron-air batteries, it has yet to be established which iron-containing material is the best cand...
Alkaline Ni-Fe batteries employ sintered iron electrodes as anodes. Iron oxide and copper powders ar...
It has recently been established that 1-octanethiol in the electrolyte can allow iron-electrodes to ...