Litcius/Paper detail

Insight into the piezo-activation of peroxymonosulfate by 1T/2H-MoS2: piezopotential boosting the formation of Mo-peroxymonosulfate complexes as the major reactive species

Tian Jiang, Chang Cai, Honggen Peng, Jianjun Li, Xiaoxiao Fu, Chunyang Nie, Zhimin Ao

2025Chemical Engineering Journal19 citationsDOIOpen Access PDF

Abstract

Piezocatalysis coupled with peroxymonosulfate (PMS)-based advanced oxidation processes (AOPs) is of current interest due to its great promise in water decontamination. MoS 2 nanoflowers (NFs) with intriguing piezoelectric properties have been widely utilized for piezo-activation of PMS, while the underlying mechanism is still controversial. Here, we conduct a thorough investigation on the mechanism involved in piezoelectric PMS activation over a multiphasic MoS 2 NFs (1T/2H-MoS 2 ) piezocatalyst. The findings demonstrate that the intrinsic active sites in 1T/2H-MoS 2 played an important role during the PMS piezo-activation process and the piezopotential mainly promoted the complexation between PMS and active sites, instead of driving the piezo-induced charges to activate PMS. Specifically, the piezo-activated 1T/2H-MoS 2 /PMS system manifests different organic substrate-dependent reactivity from the radical-based and 1 O 2 -based AOPs systems, though suppressive effects on the pollutant degradation were witnessed during the regular radical quenching tests. Further comprehensive experimental results and in situ Raman analysis suggested that surface-bounded Mo-PMS complexes instead of previously proposed free radicals and 1 O 2 are the main reactive species in the piezo-activated system. With the aid of computational modeling, the bond configurations of Mo-PMS complexes were elucidated and the thermodynamic feasibility of oxygen atom-transfer reactions between the complexes and pollutant was proved. Finally, a piezoelectric reaction column filled with 1T/2H-MoS 2 /hydrogels composites was demonstrated to be efficient for continuously removing carbamazepine in lake water due to the specific selectivity of surface-bounded Mo-PMS complexes. Our results shed new perspectives for the mechanistic understanding of piezocatalysis coupled with PMS-AOPs for water remediation.

Topics & Concepts

ChemistryBoosting (machine learning)Chemical engineeringNanotechnologyMaterials scienceEngineeringComputer scienceMachine learningAdvanced oxidation water treatmentUltrasound and Cavitation PhenomenaCorrosion Behavior and Inhibition