Oxygen Reduction Reaction of Pt and Non-PGM Transition Metal High Entropy Alloys Single Crystal Stacking Structures

Abstract: Introduction Nanoparticles of Pt as well as Pt-based alloys are widely used as cathode catalyst materials for proton exchange membrane fuel cells (PEMFC). However, electrochemical stability of the materials is rather low under practical operating conditions of PEMFC cathode, resulting in severe deactivation of oxygen reduction reaction (ORR). Therefore, further material’s developments are required for next-generation PEMFC cathode catalysts, i.e., more enhanced ORR durability wit… Show more

“…In recent years, the alloying strategy has played a signicant role in rationally designing advanced heterogeneous metal electrocatalysts and has exhibited remarkable catalytic properties for many chemical reactions. [124][125][126][127][128] The regulation of peculiar geometric and electronic structures can be achieved by the alloying strategy, providing an ideal method to deal with the scaling relationships of catalysis. In addition, the alloying strategy can induce more empty d orbitals to regulate the interaction between metal centers and reaction intermediates, which is anticipated to optimize the catalytic performance of HER catalysis.…”

Nanostructure engineering of ruthenium-modified electrocatalysts for efficient electrocatalytic water splitting

“…In recent years, the alloying strategy has played a signicant role in rationally designing advanced heterogeneous metal electrocatalysts and has exhibited remarkable catalytic properties for many chemical reactions. [124][125][126][127][128] The regulation of peculiar geometric and electronic structures can be achieved by the alloying strategy, providing an ideal method to deal with the scaling relationships of catalysis. In addition, the alloying strategy can induce more empty d orbitals to regulate the interaction between metal centers and reaction intermediates, which is anticipated to optimize the catalytic performance of HER catalysis.…”

Nanostructure engineering of ruthenium-modified electrocatalysts for efficient electrocatalytic water splitting

“…This development offers a streamlined pathway for component screening in the field of HEAs, which typically requires extensive compositional tuning. [104] Therefore, when we need to obtain surface noble metal catalysts with controllable ranges, it is necessary to determine the use of driving forces. This requires us to determine the following key indicators: types of substrates, substrate volume, the advantageous crystal structure of substrate, thickness of the noble metal layer (usually controlled by dynamic driving forces), and characteristics of the noble metal such as defects and alloying (typically influenced by post-treatments) as shown in Table 1.…”

Advances in Strain‐Induced Noble Metal Nanohybrids for Electro‐Catalysis: From Theoretical Mechanisms to Practical Use

“…[21][22][23] In comparison with homogenously disordered atomic distribution in the lattice structure, designing highly ordered facets for HEAs is promising for developing possible atomic congurations of the solute metal atoms. 24,25 On the other hand, an ultrathin nanocage structure with a few atomic layers could greatly enhance the surface-to-volume ratio, shorten the path lengths for reactants, and enhance the resistance to dissolution. [26][27][28] However, it is still a grand challenge to achieve HEA catalysts with well-dened facets and ultrathin features owing to the distinct nucleation/growth kinetics of varied compositional metals in HEAs.…”

High-entropy alloy nanocages with highly ordered {100} facets and ultrathin features for water splitting in an acidic medium