The latest news from academia, regulators
research labs and other things of interest
Posted: Nov 20, 2013
Nanotechnology leads to the world's first magnetic cellulose loudspeakers
(Nanowerk News) They're flat, ultra-thin and great-sounding. The world's first known magnetic cellulose loudspeakers have been demonstrated at KTH.
Throughout the ages, Swedes have relied on their country's vast forests as a source of sustenance and economic growth. Now add the world’s first magnetic cellulose membrane loudspeakers to the list of products that can be produced from wood.
These flat, sonorous and environmentally-friendly speakers are made with a new material derived from wood pulp – magnetic cellulose gel – which was developed at Stockholm’s KTH Royal Institute of Technology. Unlike ordinary speakers, they require no heavy permanent magnets.
The ultrathin, magnetic cellulose speakers at work.
Richard Olsson, a KTH researcher in chemical sciences who supervised the doctoral research behind the magnetic cellulose gel, says the new material may open the way for innovations in such areas as acoustic applications for automobiles.
“This is, to our knowledge, the first reported magnetic speaker membrane,” Olsson says. He adds that the sound quality is at least as good as in conventional speakers – possibly better because of the even distribution of forces created in the membrane.
The idea is to show the potential of natural and environmentally-sustainable materials in everyday products. “We want to use this first prototype to see how the cellulose can be used in new applications,” he says.
He and his research colleagues have patented the nanotechnology material, which was created by attaching magnetic nanoparticles to cellulose nanofibrils. The cellulose comes from renewable wood pulp and involves environmentally-friendly water chemistry. The gel is cast into a membrane which is then allowed to dry. The membrane’s strength is that it has a rapid reaction capability, which means a high degree of precision in sound reproduction.
Ordinary speakers include a large permanent magnet. The speaker cone's movement, which creates sound waves, is driven by a voice coil that is wrapped around the permanent magnet and attached to the cone.
With the cellulose membrane speakers, the magnetic particles are part of the membrane itself. The KTH speaker has a coil, but it has no direct contact with the cone, so the only thing that creates sound is the movement of air. All of these components can be manufactured at a very small scale.
The technology has potentially other uses, he says. “We want to look at applications for the material that are driven by magnetic fields. It may, for example, be a form of active damping for cars and trains.” It could also involve technology that cancels out noise.