The Pivotal Role of s‐, p‐, and f‐Block Metals in Water Electrolysis: Status Quo and Perspectives

Transition metals, in particular noble metals, are the most common species in metal‐mediated water electrolysis because they serve as highly active catalytic sites. In many cases, the presence of nontransition metals, that is, s‐, p‐, and f‐block metals with high natural abundance in the earth‐crust in the catalytic material is indispensable to boost efficiency and durability in water electrolysis. This is why alkali metals, alkaline‐earth metals, rare‐earth metals, lean metals, and metalloids receive growing interest in this research area. In spite of the pivotal role of these nontransition metals in tuning efficiency of water electrolysis, there is far more room for developments toward a knowledge‐based catalyst design. In this review, five classes of nontransition metals species which are successfully utilized in water electrolysis, with special emphasis on electronic structure–catalytic activity relationships and phase stability, are discussed. Moreover, specific fundamental aspects on electrocatalysts for water electrolysis as well as a perspective on this research field are also addressed in this account. It is anticipated that this review can trigger a broader interest in using s‐, p‐, and f‐block metals species toward the discovery of advanced polymetal‐containing electrocatalysts for practical water splitting. This review pioneeringly presents the unique and essential role of some s‐, p‐, and f‐block metal species enabling transition metal‐based electrocatalysts to efficiently drive hydrogen evolution and oxygen evolution reaction.