Liquid Metal Coating Creates Effective Antiviral, Antimicrobial Fabric
An international team of researchers used liquid gallium to create an antiviral and antimicrobial coating and tested it on a range of fabrics, including facemasks. The coating adhered more strongly to fabric than some conventional metal coatings, and eradicated 99% of several common pathogens within five minutes.
“Microbes can survive on the fabrics hospitals use for bedding, clothing and face masks for a long time,” says Michael Dickey, co-corresponding author of a paper on the work and Camille & Henry Dreyfus Professor of Chemical and Biomolecular Engineering at North Carolina State University. “Metallic surface coatings such as copper or silver are an effective way to eradicate these pathogens, but many metal particle coating technologies have issues such as non-uniformity, processing complexity, or poor adhesion.”
Dickey and colleagues from NC State, Sungkyunkwan University (SKKU) in Korea and RMIT University in Australia set out to develop a simple, cost-effective way to deposit metal coatings on fabric.
First, the researchers placed liquid gallium (Ga) into an ethanol solution and used sound waves – a process known as sonication – to create Ga nanoparticles. The nanoparticle solution was then spray coated onto the fabric and the Ga adhered to the fibers as the ethanol evaporated.
Then the researchers dipped the Ga-coated fabric into a copper sulfate solution, creating a spontaneous galvanic replacement reaction. The reaction deposits copper onto the fabric, creating a coating of liquid metal copper alloy nanoparticles.
To test the coated fabric’s antimicrobial properties, the research team exposed the fabric to three common microbes: Staphylococcus aureus, Escherichia coli, and Candida albicans. These microbes grow aggressively on non-coated fabrics. The copper alloy coated fabric eradicated over 99% of the pathogens within five minutes, which was significantly more effective than control samples coated with only copper.
The team collaborated with Elisa Crisci, assistant professor of virology at NC State, and Frank Scholle, associate professor of biological sciences at NC State, to show that the coatings also work against viruses. The coatings were tested against human influenza (H1N1) and coronavirus (HCoV 229E, which is in the same family as SARS-CoV-2). The coatings eradicated the viruses after five minutes.
“Our tests indicate that these liquid metal-copper coated fabrics demonstrate superior antimicrobial performance compared to other copper coated surfaces and two commercial antimicrobial facemasks that rely on copper and silver respectively,” says Vi Khanh Truong, Vice Chancellor’s Postdoctoral Fellow at RMIT University, visiting Fulbright Scholar and co-corresponding author of the research.
“This is a better method for generating metal coatings of fabrics, particularly for antimicrobial applications, both in terms of adhesion and antimicrobial performance,” says Ki Yoon Kwon, postdoctoral associate at SKKU and first author of the work.
“It could also work with metals other than copper, such as silver,” says Tae-il Kim, co-corresponding author of the research and professor at SKKU. “It is also a simple method, which should be relatively straightforward to scale up for mass production.”
The research appears in Advanced Materials and is supported by the National Research Foundation of Korea. Visiting Fulbright Scholar Samuel Cheeseman of RMIT University also contributed to the work.
Note to editors: An abstract follows.
“A Liquid Metal Mediated Metallic Coating for Antimicrobial and Antiviral Fabrics”
Authors: Ki Yoon Kwon, Haeleen Hong, Woojin Jung, Tae-il Kim, Sungkyunkwan University, Republic of Korea; Jiayi Yang, Elisa Crisci, Alba Frias-De-Diego Michael D. Dickey, Nathan Crook, Frank Scholle, North Carolina State University; Vi Khanh Truong, Samuel Cheeseman, Hong Yin, Billy J. Murdoch, RMIT University, Melbourne Australia
Published: Sept. 22, 2021 in Advanced Materials
Fabrics are widely used in hospitals and many other settings for bedding, clothing and face masks; however, microbial pathogens can survive on surfaces for a long time, leading to microbial transmission. Surface coatings with metallic particles have been widely used to eradicate pathogens. However, current metal particle coating technologies encounter numerous issues such as non-uniformity, processing complexity, and poor adhesion. To overcome these issues, we report an easy-to-control and straightforward method to coat a wide range of fabrics by using gallium liquid metal (LM) particles to facilitate the deposition of liquid metal copper alloy (LMCu) particles. Ga particles coated on the fabric provide nucleation sites for forming LMCu particles at room temperature via galvanic replacement of Cu2+ ions. The LM helps promote strong adhesion of the particles to the fabric. The presence of the LMCu particles can eradicate over 99% of pathogens (including bacteria, fungi, and viruses) within 5 min, which is significantly more effective than control samples coated with only Cu. The coating remains effective over multiple usages and against contaminated droplets and aerosols, such as those encountered in facemasks. This facile coating method is promising for generating robust antimicrobial fabrics and surfaces.
This post was originally published in NC State News.