Sound can do more than just provide a nice beat. Sound waves have been used for everything from mapping the seafloor to ...

Dajun Zhang, a doctoral student at the University of Wisconsin-Madison, has developed a new metamaterial that lets scientists ...

A newly developed metamaterial enables sound waves to manipulate objects underwater without any need for physical contact.

The invention is a metamaterial, which is a material engineered ... Another possible use lies in applications for antennae, lenses and devices that deal with wavelengths of light.

Researchers 3D print next-generation precision RF devices by combining two-photon polymerization (2PP), electroplating, and ...

While that immediately brings to mind various sci-fi possibilities when it comes to bendable or stretchable devices, MIT's new metamaterial could also make existing device classes more robust and ...

These properties could make the metamaterial useful for growing tissue repair cells in the lab, as well as for building flexible semiconductors for soft robots, wearable devices, and more.

They make use of transformation optics, a powerful technique of conformal coordinate transformations adapted from the design of metamaterial devices. As an example of their approach, the ...

Our achievements have been widely recognized, including being named a Global Cleantech 100 company. Learn more at www.metamaterial.com.

Relaxation model is absent in metamaterial research. Polarization is one of the most important electromagnetic (EM) properties of dielectric materials. The essence of polarization is electron ...

Sound waves do far more than carry music or voices. In science and engineering, they help map the seafloor, monitor earthquakes, guide submarines, and even shatter kidney stones inside the human body.