Surface Reconstruction of Water Splitting Electrocatalysts

Abstract: Gibbs free energy (ΔG) of water splitting reaction is 237.2 kJ mol −1 , corresponding to a theoretical voltage of 1.23 V. [3] However, the existence of electrochemical/concentration polarization and solution resistance can increase the actual voltage of water electrolysis to much beyond 1.23 V. Particularly, the OER involves a complicated four-electron transfer process, which results in a sluggish kinetics thus has long been the bottleneck. [4] Therefore, it is necessary to explore efficient and robust electro… Show more

“…The conjugation of different reconstruction strategies, such as surface activation, heterostructure construction, defect engineering, ionic doping, partial dissolution, and deep reconstruction, may lead to a more active catalytic surface. [ 24 , 25 ] On the other hand, excessive reconstruction may destroy the structural stability of the catalysts due to the serious dissolution of components, resulting in the loss of catalysts’ stability. [ 26 ] Therefore, the depth of reconstruction should be tuned to inhibit the dissolution of active species and eventually obtain an OER catalytic interface with efficiency and stability.…”

CoP/Fe‐Co₉S₈ for Highly Efficient Overall Water Splitting with Surface Reconstruction and Self‐Termination

“…The conjugation of different reconstruction strategies, such as surface activation, heterostructure construction, defect engineering, ionic doping, partial dissolution, and deep reconstruction, may lead to a more active catalytic surface. [ 24 , 25 ] On the other hand, excessive reconstruction may destroy the structural stability of the catalysts due to the serious dissolution of components, resulting in the loss of catalysts’ stability. [ 26 ] Therefore, the depth of reconstruction should be tuned to inhibit the dissolution of active species and eventually obtain an OER catalytic interface with efficiency and stability.…”

CoP/Fe‐Co₉S₈ for Highly Efficient Overall Water Splitting with Surface Reconstruction and Self‐Termination

“…The two important unresolved questions for TMCs as OER electrocatalysts are how the surface reconstructs during the OER and how the TMCs affect the activity/stability of the actual active sites. 163 Although there is no consensus on these open questions yet, many works in recent literature attempted to unveil the underpinning mechanism from different case studies. 164 For example, chalcogenides transformed from LDHs are recently reported showing high performance of OER 165,166 Xu et al 15 reported an iron-doped TMDs (Ni x Fe 1−x Se 2 ) derived from corresponding LDHs with edge active sites for OER.…”

“…The two important unresolved questions for TMCs as OER electrocatalysts are how the surface reconstructs during the OER and how the TMCs affect the activity/stability of the actual active sites . Although there is no consensus on these open questions yet, many works in recent literature attempted to unveil the underpinning mechanism from different case studies .…”

A Mini Review on Transition Metal Chalcogenides for Electrocatalytic Water Splitting: Bridging Material Design and Practical Application

“…[25][26][27][28][29][30][31] This in situ reconstruction process could adjust the electrocatalytic behaviors and thus improve the catalytic performance. 32 For instance, Dai and co-workers reported an outstanding hierarchical anode catalyst consisting of a nickel-iron hydroxide layer coated on a nickel sulde layer that affords superior catalytic activity and corrosion resistance in alkaline seawater electrolysis. 33 Note that the in situ generated polyanion-rich passivating layers are responsible for high corrosion resistance.…”

A dual-strategy of interface and reconstruction engineering to boost efficient alkaline water and seawater oxidation