Low-consumption water purification: Trace H2O2 triggering H2O2 generation through pollutant utilization on non-equilibrium ZnS surface.

A low-consumption water purification system is firstly constructed based on a new dual-reaction-center (DRC) catalyst molybdenum-doped zinc sulfide (Mo-ZnS, MZS) with a confined nonequilibrium surface. The extremely strong electron trapping ability of the Mo site is realized by the substitution of Mo for ZnS lattice. In this way, the electrons of emerging contaminants (ECs) are efficiently transferred to the nonequilibrium surface through the oriented interface process (Mo-S-Zn bond bridge), and obtained by the natural dissolved oxygen (DO) to generate hydrogen peroxide (H 2 O 2) under trace H 2 O 2 trigger without light and electricity assistant. The highest yield of H 2 O 2 is even up to ∼230 % of the initial value, and the ECs removal can reach 100 % within 60 min, which is far superior to conventional Fenton catalysts. This work realized the efficient utilization of the contaminant electrons through the construction of Mo-S-Zn bond bridge, which greatly reduced the energy consumption of water purification and improved the resourcefulness of ECs. [Display omitted] • DRC catalyst MZS with the confined nonequilibrium surface is first prepared. • MZS shows excellent performance for water purification. • Efficient H 2 O 2 generation is achieved without light and electricity assistant. • The highest H 2 O 2 concentration reaches up to ∼230 % of the initial concentration. • ECs electrons are efficiently utilized in ORR processes and water purification. [ABSTRACT FROM AUTHOR]