#graphene

Northwestern University researchers have developed a new water- and oil-resistant material that could become a safe, viable replacement for harmful plastics and toxic per- and polyfluoroalkyl substances (PFAS) in food packaging. Derived from graphene oxide, the material is non-toxic, environmentally friendly and affordable. When applied to paper-based food and beverage packaging, the material not only provides exceptional barrier properties but also significantly enhances the product's overall strength. This could mean an end to flimsy paper plates and soggy takeout containers. After use, packaging treated with the material can be readily composted or recycled—closing the loop on a truly sustainable solution.

A superfluid freezes and breaks the rules of physics

In a sheet of graphene, a superfluid has finally frozen—revealing a long-mysterious quantum state that blurs the line between solid and liquid.

When everyday matter is cooled, it follows a familiar path. A gas becomes a liquid, and with further cooling, that liquid turns into a solid. Quantum matter does not always follow these rules. More than a century ago, scientists discovered that helium behaves in an unexpected way at extremely low temperatures. Instead of freezing, it transforms from a normal gas into a superfluid, a rare state of matter that flows without any resistance and displays strange behaviors, including creeping up the sides of containers. Physicists have long wondered what would happen if a superfluid were cooled even further. Despite decades of effort, that question remained unanswered for nearly 50 years.

What Makes Nanotechnology so Valuable for Industrial Innovation?

A practical answer is this: nanotechnology allows engineers and researchers to work with materials at a scale where performance changes are not just smaller versions of bulk behavior.

At the nanoscale, surface area, particle interaction, optical response, conductivity, and reactivity can shift in ways that help companies design stronger, lighter, more efficient, and more functional products.

That is why nanoproducts are now relevant far beyond academic laboratories. They are being evaluated and used in electronics, energy systems, chemical processing, coatings, composites, healthcare research, agriculture, and advanced manufacturing.

For B2B buyers, the discussion is less about novelty and more about measurable performance.

Where Nanomaterials Create Value

Area

How It Creates Value

Electronics Sensors, conductive films, displays, semiconductor support materials, flexible circuits

Energy Battery materials, supercapacitors, solar cells, fuel cells, conductive additives

Chemicals Catalysts, process additives, high-reactivity powders, functional fillers

Materials Science Composites, protective coatings, polymers, ceramics, reinforcement additives

Medicine and Biotech Imaging research, diagnostics, drug delivery research, biosensing platforms

Agriculture and Environment Controlled release research, nanosensors, photocatalytic, and filtration materials

Why MKnano is Positioned For This Market

MKnano, a division of M K Impex Corp., was established in 2007 and is based in Mississauga, Canada. The company serves global markets across 35+ countries and supports industrial buyers, researchers, and technical procurement teams with a wide nanotechnology product portfolio.

Its product categories include Carbon Nanotubes (CNTs), graphene, fullerenes, buckyballs, nanoparticles, nanopowders, quantum dots, nanowires, nanorods, nano additives, nano fillers, magnetic nanoparticles, nanolubricants, and dispersions.

This breadth is important because B2B nanotechnology projects rarely depend on a single material only. Engineers often compare purity, particle size, surface chemistry, dispersion needs, and end-use requirements before choosing the right nanomaterial.