A team of international scientists have created a new form of highly-efficient, low-cost insulation based on the wings of a dragonfly.

The material, known as an aerogel, is the most porous material known to man and ultralight, with a piece the size of a family car weighing less than a kilogram.

Starting out as a wet silica gel, similar in structure to jelly, the material is carefully dried to create a strong, porous material. But until now, removing the water molecules without collapsing the fine silica structure has been a long, difficult and expensive process and as a consequence, the use of aerogels has been limited to a few highly specialist tasks, such as the collection of stardust in space.

Now a team of experts led by Newcastle University, UK, has managed to cheaply replicate the process by mimicking the way in which the dragonfly dries out its wings.

Instead of drying the silica under high temperature and pressure, the team used bicarbonate of soda (the same used to make cakes rise) to 'blow' out the water molecules, trapping carbon dioxide gas in the pores.

Publishing their findings in the academic journal Advanced Materials, the team say the next step will be to scale up the process to create larger panels that can be used to insulate our homes and buildings.

Dr Lidija Siller, joint lead author and a nanoscale scientist at Newcastle University who worked on the research with Dr Xiao Han, Khalil Hassan and Dr Adrian Oila, also of Newcastle University, explains:

"The potential of this discovery in terms of reducing energy use and therefore our energy bills is really exciting.

"Aerogels are an amazing material - safe, light and ten times more insulating than what we are using now - but until now they have been out of reach for the majority of us because they are so expensive to make. Our research is a step towards making them widely available."

Learning from nature
Dragonflies belong to the insect order known as Odonata, meaning "toothed jaw" due to their serrated mouthparts.

"These ancient insects were around long before the dinosaurs evolved," explains Dejan Kulijer, from the National Museum of Bosnia and Herzegovina.

"They are one of the oldest insect groups to take flight and include the largest insect that ever lived - the Griffenfly - that had a wingspan of more than 70 cm."

Their wings are a porous, layered structure similar to an aerogel and are so strong and light they can carry the insect up to 30 miles in an hour.

"A dragonfly's wings are an ultralight aerogel - making up less than 2% of the insect's total body weight - and yet they are so strong they can carry the insect thousands of miles across oceans and between continents," says Dr Siller, who worked on the research together with colleagues from Newcastle University, Durham University and Limerick University, Ireland, as well as experts from the National Museum of Bosnia and Herzegovina.

"Most of its lifecycle, the dragonfly spends underwater in its larval stage (a period ranging from 30 days to several years). The change from larva to the adult flying insect represents irreversible changes in morphology and physiology. This process of metamorphosis can take between 20 min up to several hours, depending on the species. When the dragonfly emerges from its larval skin, its wings are like jelly but within a very short time they expand and harden to become completely dry.

"To achieve this, their bodies produce bicarbonate molecules which release carbon dioxide gas that regulates body pressure and dries wings at the same time. This 'blows' out the water to leave a dry, stable, light and strong structure.

"We replicated this process in the lab with the aerogel, blowing out the water at ambient temperature and with sodium bicarbonate."

Ideal insulators
Aerogels were first discovered in 1931. Typically weighing around 0.1g/cm3 and made up of 95% air, they have a thermal conductivity similar to a vacuum panel making them ideal insulators - not just to keep warmth in, but also keep homes cool.

Their insulating properties and robustness against ageing, moisture and perforation make them ideal materials for insulation in buildings but until now the high cost of production has limited their use.

By adding bicarbonate solvents into the silica gels and utilising an innovative chemical process, the team forced the production of carbon dioxide to dry out the gel from the inside out. At the same time, the CO2 is trapped in the delicate structure, preventing the collapse of the aerogel.

Joint lead author Dr Xiao Han, Newcastle University, said the new technique would reduce the cost of production by 96% - from around $100 to $4 per kilogram.

"Just like a dragonfly's wings, our aerogel material is made up of ultra-thin layers of silica which means we can create a stronger structure. The next step will be to scale up the process to produce panels of the insulation that can be used in homes and buildings to help reduce our energy use and ultimately, our bills."

Research paper

Related Links
Newcastle University
Space Technology News - Applications and Research

Tweet

Thanks for being here; We need your help. The SpaceDaily news network continues to grow but revenues have never been harder to maintain. With the rise of Ad Blockers, and Facebook - our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don't have a paywall - with those annoying usernames and passwords. Our news coverage takes time and effort to publish 365 days a year. If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
SpaceDaily Contributor $5 Billed Once credit card or paypal		SpaceDaily Monthly Supporter $5 Billed Monthly paypal only

Watching nanomaterials form in 4-D
Evanston IL (SPX) Apr 26, 2018
When famed physicists Max Knoll and Ernst Ruska first introduced the transmission electron microscope (TEM) in 1933, it allowed researchers to peer inside cells, microorganisms and particles that were once too small to study. For decades, these high-powered instruments had been limited to taking static snapshots of specimens, which only tell part of the story. Now researchers from Northwestern University and the University of Florida are filling in the blanks to make this story more complete. ... read more