HKUST Researchers Develop the World’s Strongest Polymer Nanomembrane
Researchers from the Hong Kong University of Science and Technology (HKUST) have developed an ultrathin polymer nanofilm, which is not only 25 times stronger1 than stainless steel with the same mass, but is also extremely transparent, gas-permeable and water-proof with adjustable porous properties, making it suitable for use as wearable devices, medical protection, desalination, electronics, solar cells and many other cutting-edge technologies.
Since the onset of the COVID-19 pandemic, the team led by Prof. GAO Ping, Professor of Chemical and Biological Engineering and Acting Head of the Advanced Materials Thrust at HKUST(GZ), has been studying how to build a transparent and breathable face mask with their novel advanced material. After months of efforts the team has finally produced a prototype with a 99% filtration efficiency for virus, bacteria and particulate matters under tests in line with NIOSH NaCI (N95 respirator testing standard)2.
“This novel material has many potential, but since the pandemic struck, we focus on turning our nanofilm into a face mask that is not only transparent and breathable, but is also highly efficient against virus and bacteria, as we haven’t yet seen one in the market which bears all three properties,” said Prof. Gao. “While common opaque surgical masks can protect the wearer from infection, they are not convenient for the hearing-impaired people who need to communicate via lip reading and facial language; or teachers, child carers or performers who rely heavily on facial expressions in teaching, nurturing or performance.”
Apart from face mask, the team has also filed six other patents for the material’s application in other areas. The nanofilm’s adjustable porous property, for example, has made it the world’s most potent polymeric membrane for membrane distillation desalination so far, with an efficiency 10 times higher than existing products in the market and almost three times above world record.
Meanwhile, its conformity, antibacterial, transparent yet strong properties has also made it an ideal material for various biomedical causes, including a new generation of wound dressing which requires no daily replacement and allows direct application of medicine.
“Wound dressing made with this nanofilm is particularly useful for patients who suffer large-scale burns,” said Prof. Gao. “It acts like a temporary skin to the burn victim. Doctors can apply medicine directly over the film, which would filter through to the wound beneath. As the film is completely water-proof, wearers can even take a shower without fearing of wetting the wound.”
The material also makes a much better motion sensor for people, as it can be adopted for the design of robotic motions. Apart from biomedical and environmental use, the nanofilm can also be applied to electrical appliances, such as nanovibrational speaker with higher resolution of audio output or ultrathin batteries and high-energy density capacitors.
This nanofilm developed by the team – measuring just 20 nanometers or less than one thousandth the thickness of a hair strand – is made from the ultra-high-molecular-weight polyethylene (UHMWPE), a light-weight material used in bullet-proof vest. It was very difficult to reduce UHMWPE to nanoscale as the powder-like material breaks at a certain level under the conventional methodology which stretches it in opposite directions to change the intrinsic orientation of the disordered and entangled polymeric chain.
But Prof. Gao found a way to detangle the polymer chains. Similar to applying conditioner to smoothen the hair, Prof. Gao’s team put UHMWPE into a lubricant and transform the material into a gel form, successfully enhancing its drawability while preventing the polymer chains from knotting. The team is thus able to rearrange the polymer chains into a topologically triangulated stable structure - a structure where some of the strongest material built upon.
Prof. Gao’s PhD student GU Qiao as well as CHEUNG Shu-Kwan and Walter LEE from Design and Manufacturing Services Facility of HKUST have helped designing the transparent face mask.
1. Stronger in terms of specific strength. While strength is commonly known as the amount of force a material could bear per unit area, specific strength is another concept which takes density into account. For example, steel and titanium can hold the same amount of force in the same area but titanium has higher specific strength as it is lighter than steel. Specific strength is especially important in the field of aerospace technology, as lightweight but robust mechanics are necessary for making aircrafts.
2. Sodium Chloride Aerosol Challenge (NaCl) is a respirator prequalification test adopted by The National Institute for Occupational Safety and Health (NIOSH) to evaluate particle penetration and air flow resistance properties of a variety of filtration materials. This testing method is much stricter than U.S. Food and Drug Administration (FDA) approved surgical mask testing method.
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About The Hong Kong University of Science and Technology
The Hong Kong University of Science and Technology (HKUST) (www.ust.hk) is a world-class research intensive university that focuses on science, technology and business as well as humanities and social science. HKUST offers an international campus, and a holistic and interdisciplinary pedagogy to nurture well-rounded graduates with global vision, a strong entrepreneurial spirit and innovative thinking. HKUST attained the highest proportion of internationally excellent research work in the Research Assessment Exercise 2014 of Hong Kong’s University Grants Committee, and is ranked as the world’s best young university in Times Higher Education’s Young University Rankings 2020. Its graduates were ranked 26th worldwide and among the best from universities from Asia in Global University Employability Survey 2020.
(This news was originally published by the HKUST Public Affairs Office here.)