Abstract
The oxygen reduction reaction is one ofthe limiting stepsin microbial fuel cell
performance. M-N-C catalysts (M as transition metal) represent the best compromise of optimal cost, electrocatalytic activity and durability. The Fe-based catalysts were shown to be the best compared to Co-, Mn-, Ni-based catalysts. The addition of the second transition metal such as Mn was shown to increase the selectivity of the reaction and reduce peroxide production. The use of different N-C precursors resulted in diverse surface chemistry that directly affects the performance. Generally, surface chemistry plays a critical role in the electrocatalytic activity. Integration of the catalyst in the air-breathing cathode is also discussed with a performance that is enhanced by: i) increasedcatalyst loading; ii) the addition of graphene to structure.
performance. M-N-C catalysts (M as transition metal) represent the best compromise of optimal cost, electrocatalytic activity and durability. The Fe-based catalysts were shown to be the best compared to Co-, Mn-, Ni-based catalysts. The addition of the second transition metal such as Mn was shown to increase the selectivity of the reaction and reduce peroxide production. The use of different N-C precursors resulted in diverse surface chemistry that directly affects the performance. Generally, surface chemistry plays a critical role in the electrocatalytic activity. Integration of the catalyst in the air-breathing cathode is also discussed with a performance that is enhanced by: i) increasedcatalyst loading; ii) the addition of graphene to structure.
| Original language | English |
|---|---|
| Journal | Current Opinion in Electrochemistry |
| Publication status | Accepted/In press - 12 Jun 2020 |
Keywords
- oxygen reduction reaction
- microbial fuel cells
- cathode catalyst
- air-breathing cathode
- platinum group metal-free
