Ru doped CoP nanosheets for efficient hydrogen evolution in microbial electrolysis cells

Abstract: Microbial Electrolysis Cells (MECs) is an emerging hydrogen production technology that can potentially purify wastewater at anode and simultaneously produce hydrogen at cathode. Development of low-cost and high-efficiency catalyst toward...

“…To expand the applicability of MECs, it is necessary to study wastewater treatment and energy generation under different pH conditions. 21,22 In addition, Rago et al showed that the hydrogen production performance of microbial electrolytic cells under alkaline conditions was nearly 1.2 times that under neutral conditions. 23 Therefore, it has great prospects to configure asymmetric neutral alkaline MECs with bases as catholytes to optimize the environmental conditions of the cathode and further improve the performance of MECs.…”

“…To expand the applicability of MECs, it is necessary to study wastewater treatment and energy generation under different pH conditions. 21,22 In addition, Rago et al…”

N-doped Mo₂C particles as a cathode catalyst of asymmetric neutral-alkaline microbial electrolysis cells for hydrogen production

“…To expand the applicability of MECs, it is necessary to study wastewater treatment and energy generation under different pH conditions. 21,22 In addition, Rago et al showed that the hydrogen production performance of microbial electrolytic cells under alkaline conditions was nearly 1.2 times that under neutral conditions. 23 Therefore, it has great prospects to configure asymmetric neutral alkaline MECs with bases as catholytes to optimize the environmental conditions of the cathode and further improve the performance of MECs.…”

“…To expand the applicability of MECs, it is necessary to study wastewater treatment and energy generation under different pH conditions. 21,22 In addition, Rago et al…”

N-doped Mo₂C particles as a cathode catalyst of asymmetric neutral-alkaline microbial electrolysis cells for hydrogen production

High-temperature shock enabled synthesis of ultrafine Ru nanoparticles anchoring onto tungsten carbide with strong metal-support interaction for ampere-level current density hydrogen evolution