Rutgers scholar is a pioneer in acoustic cloaking research

Rutgers professor Andrew Norris is developing honeycomb-like metallic structures to reroute sound waves, creating the impression that both a cloak and anything beneath it are not there – like Harry Potter's cloak of invisibility.
Image: Sam Aranov/Shutterstock

Andrew Norris, a professor in the  Department of Mechanical and Aerospace Engineering at Rutgers University-New Brunswick, is a pioneer in a field known as cloaking, which can help make underwater objects appear invisible. He has created a model for directing sound waves to go around — instead of colliding with — an object, hiding it from detection. Rutgers Today asked Norris to discuss his research, which could lead to improved acoustic technology, including better imaging underwater, and biomedical applications, such as enhanced imaging of tissue. 

What is cloaking?

Cloaking is sort of synonymous with invisibility, like when Harry Potter wears an invisibility cloak. He puts it on and disappears. There are lots of sci-fi references to invisibility – the (comic book characters) Invisible Woman and the Invisible Man. They have cloaking devices in Star Trek. So, it’s always been of interest in literature, in society and in science. During the last 20 years or so, people have realized it’s possible to achieve one kind of cloaking – the basic idea is to control sound waves in ways you couldn’t before.

What do you study?

We study acoustics – sound that can be in the air, fluids and solids. Generally, we use mathematical models to explore possibilities for different kinds of devices and see how we might control sound. We often find things that we didn’t expect. We can make effects that might appear impossible, but everything is based on the laws of physics. Much of our work involves designing and testing innovative materials and structures to control how sound waves move.

This image shows how different types of fluid could be combined to provide an acoustic cloak. It was motivated by the author's fondness for Easter eggs, especially large eggs with smaller ones inside.
Image: Professor Andrew Norris/Rutgers University-New Brunswick
What have been your major findings?

Our findings are in the field of cloaking. A cloak bends the light around an object so it is invisible. The same concepts apply to other kinds of waves, including sound. To make a cloak for sound or light, you must be able to make new forms of material that can bend the waves around the object inside the cloak. We are focusing on developing a new material design using metallic lattices. Our lattice consists of relatively thin metal pieces arranged in a honeycomb pattern if the structure is two-dimensional, and like a diamond structure in 3D. While these structures cannot yet make cloaking devices, we found they can be used in other unexpected applications, such as making underwater acoustic lenses. We designed a lens that focuses and amplifies sound. The lens is novel because no power is necessary and it can focus acoustic energy in a small region, magnifying the signal from a distant sound source. We also designed an underwater device that can redirect acoustic energy from a hydrophone. A hydrophone produces sound underwater, but the sound energy is directed almost equally in all directions.

Why are your findings important and what are the practical implications?

Acoustics is central in communications, whether the sound provides useful information or annoying noise. Our research has developed theoretical and practical methods to better understand how to control sound. Our focus is on applications for underwater sound, such as sonar sound waves used in communicating and locating things. The Navy has expressed interest. Everyone asks whether a cloak could make a submarine invisible, but that is quite unrealistic. The size of any effective cloak would dwarf the sub. We also could see applications in commercial devices. Examples would be improved acoustic imaging underwater for finding fish or imaging the ocean bottom. Biomedical applications could include better imaging of tissue, which is very much like water when it comes to acoustics.