The degradation of organic pollutants in water is a critical environmental challenge.The iron-doped MoS_(2) catalysts have demonstrated potential in activating peroxymonosulfate(PMS)for environmental remediation,but t...The degradation of organic pollutants in water is a critical environmental challenge.The iron-doped MoS_(2) catalysts have demonstrated potential in activating peroxymonosulfate(PMS)for environmental remediation,but they face challenges such as poor conductivity,limited electron transfer efficiency,and a scarcity of active sites.To address these issues,we successfully synthesized a nano-flowers FeS/MoS_(2) composite derived from polyoxometalates(NH_(4))_(3)[Fe(III)Mo_(6)O_(24)H_(6)]⋅6H_(2)O(denoted as FeMo6)as the bimetallic precursors.This synthesis strategy enhances the interaction between FeS and MoS_(2),thereby facilitating electron transfer.Notably,the introduction of sulfur vacancies in FeS/MoS_(2) exposes additional Mo4t active sites,promoting the redox cycle of Fe^(2+)/Fe^(3+) and accelerating the regeneration of Fe^(2+),which in turn enhances PMS activation.Therefore,a catalytic oxidation system of FeS/MoS_(2)/PMS is presented that primarily relies on SO_(4)^(⋅-)and⋅OH,with ^(1)O_(2) as a supplementary oxidant.This system exhibits exceptional degradation efficiency for p-chlorophenol(4-CP),achieving 100% degradation within 10 min over a wide pH range of 2.4–8.4.The robust performance and wide applicability of FeS/MoS_(2) catalyst make it a promising candidate in advanced oxidation processes(AOPs)for environmental remediation.展开更多
基金financially supported by the National Natural Science Foundation of China(52063024 and 51868052)the Natural Science Foundation of Jiangxi Province(20192ACBL21046)the National Science Foundation of State Key Laboratory of Structural Chemistry(20160013).
文摘The degradation of organic pollutants in water is a critical environmental challenge.The iron-doped MoS_(2) catalysts have demonstrated potential in activating peroxymonosulfate(PMS)for environmental remediation,but they face challenges such as poor conductivity,limited electron transfer efficiency,and a scarcity of active sites.To address these issues,we successfully synthesized a nano-flowers FeS/MoS_(2) composite derived from polyoxometalates(NH_(4))_(3)[Fe(III)Mo_(6)O_(24)H_(6)]⋅6H_(2)O(denoted as FeMo6)as the bimetallic precursors.This synthesis strategy enhances the interaction between FeS and MoS_(2),thereby facilitating electron transfer.Notably,the introduction of sulfur vacancies in FeS/MoS_(2) exposes additional Mo4t active sites,promoting the redox cycle of Fe^(2+)/Fe^(3+) and accelerating the regeneration of Fe^(2+),which in turn enhances PMS activation.Therefore,a catalytic oxidation system of FeS/MoS_(2)/PMS is presented that primarily relies on SO_(4)^(⋅-)and⋅OH,with ^(1)O_(2) as a supplementary oxidant.This system exhibits exceptional degradation efficiency for p-chlorophenol(4-CP),achieving 100% degradation within 10 min over a wide pH range of 2.4–8.4.The robust performance and wide applicability of FeS/MoS_(2) catalyst make it a promising candidate in advanced oxidation processes(AOPs)for environmental remediation.
