Lattice‐Matching Formed Mesoporous Transition Metal Oxide Heterostructures Advance Water Splitting by Active Fe–O–Cu Bridges

Abstract: carbon-intensive fuels. Hydrogen represents a versatile fuel with high energy density and low carbon emission. In 2020, the global hydrogen generation market size was valued at ≈120 billion USD and is expected to rapidly expand. Presently, industrial hydrogen is primarily acquired from natural gas reforming that involves energy-consuming processes with extensive greenhouse gas release. Alternatively, electrochemical water splitting is a sustainable technique to store the intermittent electricity and produce hi… Show more

“…Moreover, the interface area in the electrode can increase the active sites with unique electrochemical behaviors, thus affording an admirable electrochemical performance. 19,20,55 In short, benefiting from structural and compositional advantages, the hierarchical Ni(OH) 2 -MnO 2 hollow spheres are demonstrated to be a desirable candidate electrode material for supercapacitors.…”

Hierarchical Ni(OH)₂–MnO₂hollow spheres as an electrode material for high-performance supercapacitors

“…Moreover, the interface area in the electrode can increase the active sites with unique electrochemical behaviors, thus affording an admirable electrochemical performance. 19,20,55 In short, benefiting from structural and compositional advantages, the hierarchical Ni(OH) 2 -MnO 2 hollow spheres are demonstrated to be a desirable candidate electrode material for supercapacitors.…”

Hierarchical Ni(OH)₂–MnO₂hollow spheres as an electrode material for high-performance supercapacitors

“…Numerous energy storage systems with superior electrochemical performance (long cycle stability and high energy density/power density) have emerged since the first commercialization of rechargeable lithium‐ion batteries in 1990, including sodium‐ion batteries, [ 1–3 ] lithium‐sulfur batteries, [ 4–6 ] aqueous batteries, [ 7,8 ] supercapacitors, [ 9,10 ] and so on. [ 11–16 ] Meanwhile, the batteries often have extremely high energy densities, but they have a short cycle life and safety risks due to severe redox reactions and dendritic complications. On the contrary, supercapacitors exhibit a higher power density and longer cycle life, owing to the fast and reversible ion adsorption/desorption at the electrode/electrolyte interface, whereas their energy density (5–10 Wh kg −1 ) is much lower than that of batteries.…”

Zinc‐ion hybrid supercapacitors: Design strategies, challenges, and perspectives

“…[18][19][20][21] However, the development of TMOs is hindered because of the limited number of active sites and poor electrical conductivity. [22][23][24][25] In this regard, various emerging strategies have been employed to optimize the performance of TMO electrocatalysts, among which heteroatom doping is one of the main research areas. [26][27][28] Elemental doping as a facile technique effectively improves the electronic structure and the active area of TMOs to enhance their intrinsic activity.…”

Electronic modulation of cobalt–molybdenum oxideviaTe doping embedded in a carbon matrix for superior overall water splitting