Litcius/Paper detail

Highly efficient microbial inactivation enabled by tunneling charges injected through two-dimensional electronics

In‐Yong Suh, Zheng‐Yang Huo, Jae-Hwan Jung, Donghyeon Kang, Dong‐Min Lee, Young‐Jun Kim, Bosung Kim, Jinyoung Jeon, Pin Zhao, Jeonghune Shin, SeongMin Kim, SeongMin Kim, Sang-Woo Kim, Sang-Woo Kim

2024Science Advances18 citationsDOIOpen Access PDF

Abstract

Airborne pathogens retain prolonged infectious activity once attached to the indoor environment, posing a pervasive threat to public health. Conventional air filters suffer from ineffective inactivation of the physics-separated microorganisms, and the chemical-based antimicrobial materials face challenges of poor stability/efficiency and inefficient viral inactivation. We, therefore, developed a rapid, reliable antimicrobial method against the attached indoor bacteria/viruses using a large-scale tunneling charge-motivated disinfection device fabricated by directly dispersing monolayer graphene on insulators. Free charges can be stably immobilized under the monolayer graphene through the tunneling effect. The stored charges can motivate continuous electron loss of attached microorganisms for accelerated disinfection, overcoming the diffusion limitation of chemical disinfectants. Complete (>99.99%) and broad-spectrum disinfection was achieved <1 min of attachment to the scaled-up device (25 square centimeters), reliably for 72 hours at high temperature (60°C) and humidity (90%). This method can be readily applied to high-touch surfaces in indoor environments for pathogen control.

Topics & Concepts

MonolayerMicroorganismNanotechnologyQuantum tunnellingGrapheneMaterials scienceOptoelectronicsChemistryBacteriaBiologyGeneticsInfection Control and VentilationDental Research and COVID-19Inhalation and Respiratory Drug Delivery
Highly efficient microbial inactivation enabled by tunneling charges injected through two-dimensional electronics | Litcius