Fe-Fe Double-Atom Catalysts for Murine Coronavirus Disinfection: Nonradical Activation of Peroxides and Mechanisms of Virus Inactivation.
Zhe ZhouMengqiao LiYuxin ZhangLingchen KongVirginia F SmithMengyang ZhangAnders J GulbrandsonGordon H WallerFeng LinXitong LiuDavid P DurkinHanning ChenDanmeng ShuaiPublished in: Environmental science & technology (2023)
Peroxides find broad applications for disinfecting environmental pathogens particularly in the COVID-19 pandemic; however, the extensive use of chemical disinfectants can threaten human health and ecosystems. To achieve robust and sustainable disinfection with minimal adverse impacts, we developed Fe single-atom and Fe-Fe double-atom catalysts for activating peroxymonosulfate (PMS). The Fe-Fe double-atom catalyst supported on sulfur-doped graphitic carbon nitride outperformed other catalysts for oxidation, and it activated PMS likely through a nonradical route of catalyst-mediated electron transfer. This Fe-Fe double-atom catalyst enhanced PMS disinfection kinetics for inactivating murine coronaviruses (i.e., murine hepatitis virus strain A59 (MHV-A59)) by 2.17-4.60 times when compared to PMS treatment alone in diverse environmental media including simulated saliva and freshwater. The molecular-level mechanism of MHV-A59 inactivation was also elucidated. Fe-Fe double-atom catalysis promoted the damage of not only viral proteins and genomes but also internalization, a key step of virus lifecycle in host cells, for enhancing the potency of PMS disinfection. For the first time, our study advances double-atom catalysis for environmental pathogen control and provides fundamental insights of murine coronavirus disinfection. Our work paves a new avenue of leveraging advanced materials for improving disinfection, sanitation, and hygiene practices and protecting public health.
Keyphrases
- metal organic framework
- visible light
- drinking water
- electron transfer
- human health
- molecular dynamics
- public health
- highly efficient
- sars cov
- aqueous solution
- risk assessment
- primary care
- climate change
- healthcare
- quantum dots
- nitric oxide
- emergency department
- cell death
- induced apoptosis
- room temperature
- signaling pathway
- smoking cessation
- transition metal
- electronic health record
- single molecule