Graphene Oxide: Introduction and Market News

Researchers from Monash University and The Pennsylvania State University, In collaboration with NematiQ, a wholly owned subsidiary of Clean TeQ Water, have developed a novel water filtration membrane that effectively removes small PFAS molecules (a group of man-made chemicals known for their persistence and resistance to breakdown), overcoming a significant challenge faced by conventional water filters.

PFAS cycle. Image credit: Clean TeQ Water

The team designed a beta-cyclodextrin (βCD) modified graphene oxide (GO-βCD) membrane with nanoscale channels that selectively retain PFAS while allowing water to pass through.

Modern cancer treatments have evolved beyond traditional chemotherapy to include targeted approaches such as immunotherapy, radiation therapy, and photothermal therapy. Graphene oxide (GO) has emerged as a promising material for both drug delivery and thermal-based tumor destruction. However, its clinical application remains limited due to challenges in dispersibility and large-scale production.

To overcome these limitations, Professor Eijiro Miyako and his research team from the Japan Advanced Institute of Science and Technology (JAIST) have developed a novel GO nanocomposite enhanced with bacterial components. The study highlights how bacterial properties improve GO's effectiveness in cancer therapy. Certain bacteria naturally stimulate immune responses and enhance dispersibility of GO due to their amphiphilic cellular components.

Researchers from KTH Royal Institute of Technology, University of New South Wales and University of Milan have a reported a reproducible and scalable method for producing graphene oxide (GO) nanosheets from commercial carbon fibers. The process involves exfoliating carbon fibers with nitric acid, which reportedly provides high yields of one-atom-thick sheets of graphene oxide with characteristics comparable to commercial GO sourced from mined graphite.

The GO production process, from commercial carbon fibers to graphene sheets. Image from: Small

The team explained that the proof of concept was carried out with carbon fibers derived from polyacrylonitrile (PAN), a widely available polymer that undergoes high-temperature oxidation and graphitization. The method could be duplicated with other raw sources, such as raw sources such as biomass or forest industry sidestreams.

PEDOT, short for poly(3,4-ethylenedioxythiophene), is a flexible, transparent film often applied to the surfaces of photographic films and electronic components to protect them from static electricity. It is also found in touch screens, organic solar cells and electrochromic devices, such as smart windows. However, PEDOT’s potential for energy storage has been limited because commercially available PEDOT materials lack the electrical conductivity and surface area needed to hold large amounts of energy.

An example of how EDOT monomer vapors react with a droplet of graphene oxide and ferric chloride to form PEDOT nanofibers. Image credit: UCLA

UCLA chemists have addressed these challenges with an innovative method that makes use of graphene oxide to control the morphology of PEDOT to grow nanofibers precisely. These nanofibers exhibit exceptional conductivity and expanded surface area, both of which are crucial for enhancing the energy storage capabilities of PEDOT. This approach demonstrates the potential of PEDOT nanofibers for supercapacitor applications.

Researchers at the National University of Singapore (NUS), and Deliarts recently presented an interdisciplinary approach combining materials science, ultrasonication, artistic expression, and curatorial practice to develop graphene-enhanced ceramics, improving strength and aesthetics. The focus of the approach was incorporating graphene oxide (GO) into kaolin clay and exploring its effects on material properties. 

Image taken from: technologynetworks.com, Credit: Daria Andreeva, National University of Singapore, and Delia Prvački, Deliarts Pte Ltd.

In recent years, scientists have been adding GO to ceramic slurries — consisting of particles of kaolin clay or other materials dispersed in water — to make fired ceramics more durable and resistant to thermal shock. The team adapted this technique by using ultrasound to better mix the GO into kaolin slurries. They adjusted GO concentration and ultrasound exposure time to find the conditions that most enhanced the resulting ceramics’ strength and heat resistance. The team also collaborated with artist-in-residence Delia Prvački, who created works from the new ceramic material that are on display at the National University of Singapore Museum. 

Researchers at the National University of Singapore, working with colleagues from Manchester University and Guangdong University of Technology, have developed a sponge-like material made of graphene oxide and chitosan, that can be used to extract gold from electronic waste. In their recent study, the research team describes how they made their sponge and how well it worked during testing.

Previous research has shown that removing gold, silver and other metals from electronic equipment that is no longer useful, as a way to recycle such materials, is a difficult task that often results in low yields and the generation of a variety of toxic pollutants. In this new work, the team has found a way to remove the gold in a way that is cheaper and cleaner than conventional methods and much more efficient as well.

Singapore-based Memsift Innovations has entered into a technology transfer agreement with Singapore’s Ngee Ann Polytechnic on an innovative graphene membrane technology.

It was explained that the technology, featuring graphene oxide-based hollow fiber ultrafiltration and nanofiltration membranes, was developed based on over a decade of research and development. The ultrafiltration technology utilizes a graphene oxide-block copolymer composite renowned for its exceptional chemical and thermal stability, making it ideal for harsh industrial applications. Its unique surface chemistry forms a protective water layer that effectively prevents fouling. The nanofiltration technology employs a robust single-layer modified graphene oxide membrane with synthetic water channels, enhancing selectivity and permeability. This enables efficient molecular-level separation and differentiation between monovalent and multivalent ions.

While graphene aerogels have advantageous properties like extremely low weight, high porosity and good electrical conductivity, engineers who tried to use them to develop pressure sensors have encountered some difficulties. 

Image credit: Nano Letters 2024

Specifically, many of these materials have an intrinsically stiff microstructure, which poses limits on their strain sensing capabilities. Researchers from Xi'an Jiaotong University, Northumbria University, UCLA, University of Alberta and other institutes recently introduced a new fabrication strategy for synthesizing aerogel metamaterials to overcome this limitation. This strategy fabricates a durable graphene oxide-based aerogel metamaterial that exhibits a remarkable sensitivity to human touch and motion.

A research team from Skoltech, MIPT, Emanuel Institute of Biochemical Physics of Russian Academy of
Sciences, and other scientific organizations recently conducted a study to determine which conditions are the most suitable for storing graphene oxide.

The results showed that the most optimal conditions for graphene oxide, when its properties will not change, are low temperatures and a lack of light. 

Researchers from Kumamoto University and Hiroshima University have announced a significant development in hydrogen ion barrier films using graphene oxide (GO) without internal pores. This approach could be beneficial for protective coatings for various applications.

In their study, the research team successfully synthesized and developed a pore-free GO (Pf-GO) membrane with controlled oxygen functional groups. Traditionally, GO has been known for its high ionic conductivity, which made it challenging to use as an ion barrier. However, by eliminating the internal pores, the team created a material with dramatically improved hydrogen ion barrier properties.