Finding Inspiration for Technical Ceramics in the Unlikeliest Places (Eg, the floor of the Indian Ocean)

Structural ceramics have many uses--water filtration, shielding, armor--and they're created and engineered by some of the biggest brains in the world. However, sometimes mother nature can teach us that there's more under the sun than the innovations of man. Scientists at UC Berkeley have discovered that a snail called the scaly-foot gastropod, known for over a decade as inhabiting a hydrothermal vent field in the Indian Ocean, sports a shell that is amazingly resistant to extreme temperature, pressure, acidity, and physical impact. Sounds a lot like advanced technical ceramics, right?

Robert Ritchie, a scientist at UC Berkeley, says,

"If you look at the individual properties of the bits and pieces that go into making this shell, they’re not very impressive, but the overall thing is.”

Scientists at MIT concluded by using nanoscale experiments and computer simulations that the snail's shell uses "mechanical property amplification," an attribute that allows for the shell to be hundreds of times harder than the sum of its parts. The gastropod's shell is thicker than most other species', and it uses iron sulfide in its material composition. Scientists' larger goal, of course, is to leverage the natural ingenuity of the scaly-foot gastropod's shell into practical applications: armor, helmets, heat shields, corrosive containment. Ritchie believes it will be a while until marketable products are made using the lessons learned from the snail, but his lab is already working on creating a ceramic material based on its properties. For more information, check out this Wired article about this durable little deep-sea snail.

Georgia Tech Researchers Discovery Mystery Ceramic

Researchers at Georgia Tech have created a new ceramic material that could have revolutionary applications in fuel cell technology. It is still in a nascent, developmental stage, but it could reduce tremendously the cost of creating fuel cells. The high cost of fuel cells has been a barrier to their wider adoption.

The Georgia Tech researchers were supported by the U.S. Department of Energy’s Basic Energy Science Catalysis Science Program. Using the government money, they developed a new material for use in solid oxide fuel cells (SOFC). A SOFC generally uses a ceramic electrolyte, which in this case is a yttria-stabilized zirconia (YSZ) ceramic. Traditionally, YSZ operates poorly in an SOFC because it is inefficient, clogs easily, and must operate at a high temperature due to its poor conductivity at low temperatures. The new ceramic material, though, gets around all these drawbacks.

The material is a Barium-Zirconium-Cerium-Yttrium-Ytterbium Oxide (BZCYYb), which can be used as a coating on a traditional anode or a replacement for YSZ altogether. It has been lab-proven for performance up to 1,000 hours of continuous use, but it requires more testing to determine its stability and lifespan.

Researcher Meilin Liu says,

“Solid oxide fuel cells offer high energy efficiency, the potential for direct utilization of all types of fuels including renewable biofuels, and the possibility of lower costs since they do not use any precious metals... We are working to reduce the cost of solid oxide fuel cells to make them viable in many new applications, and this new material brings us much closer to doing that.”