Novel ceramic remembers to change shape

Shape-memory metals, which can revert from one shape to a different one simply by being warmed or otherwise triggered, have proved useful in a variety of applications, including as actuators that can control the movement of various devices. Now, the discovery of a new category of shape-memory materials made of ceramic rather than metal could open up a new range of applications, especially for high-temperature settings, such as actuators inside a jet engine or a deep borehole.

The new findings by former doctoral student Edward Pang and professors Gregory Olson and Christopher Schuh in the Department of Materials Science and Engineering at Massachusetts Institute of Technology (MIT) are reported in a paper in Nature.

Shape-memory materials have two distinct shapes, and can switch back and forth between them. They can be easily triggered by temperature, mechanical stress, or electric or magnetic fields to change shape in a way that exerts force.

“They are interesting materials because they’re sort of like a solid-state piston,” says Schuh – in other words, a device that can push against something. But while a piston is an assembly of many parts, a “shape-memory material is a solid-state material that does all of that. It doesn’t need a system. It doesn’t need many parts. It’s just a material, and it changes its shape spontaneously. It can do work. So, it’s interesting as a ‘smart material’.”

Shape-memory metals have long been used as simple actuators in a variety of devices, but they are limited by the achievable service temperatures of the metals used, usually a few hundred degrees Celsius at most. Ceramics can withstand much higher temperatures, sometimes up to thousands of degrees, but are known for their brittleness. Now, the MIT team has found a way to overcome that to produce a ceramic material that can actuate without accumulating damage, thus allowing it to function reliably as a shape-memory material through many cycles of use.

“The shape-memory materials that are out there in the world, they’re all metal,” says Schuh. “When you change a material’s shape down at the atomic level, there’s a whole lot of damage that can be created. Atoms have to reshuffle and change their structure. And as atoms are moving and reshuffling, it’s sort of easy to get them in the wrong spots and create defects and damage the material, which leads them to fatigue and eventually fall apart.

“You end up with materials that can deform a few times, but then eventually they degrade and they can fall apart. And because metals are so ductile, they’re a little more damage resistant, and so the field has really focused on metals because when a metal is damaged on the inside, it can tolerate it.”

Ceramics, by contrast, don’t tolerate damage well at all, and rather than bend they usually fracture. Zirconia is one ceramic known to have a shape-memory property, but it accumulates damage very easily during a shape-memory cycle — a property measured as high hysteresis.

“What we wanted to do with this work was design a new ceramic and specifically target that hysteresis,” Schuh explains. “We wanted to design a ceramic where the [shape] transformation is somehow still gigantic: We want to do a lot of work. But internally, at the atomic scale, it’s more gentle.”

Schuh explains that Pang, who led the work, “took all of the modern tools of science, everything you can name – computational thermodynamics, phase transformation physics, crystallographic calculations, machine learning – and he put all these tools together in a totally new way” in order to solve the problem of creating such a material.

The result was a new version of zirconia. “Basically, it’s zirconia,” Schuh explains. “It looks and smells and tastes just like zirconia that people already know and use, including like cubic zirconia in jewelry.” But some atoms of different elements have been introduced into its structure in a way that alters some of its properties. These elements “dissolve into the lattice, and they sculpt it, and they change that transformation, they make it more gentle at the atomic scale”.

The hysteresis changed so dramatically that it now resembles that of metals, Schuh says. “That was a huge, huge change – we’re talking about a factor of 10.” And the deformation that the material can achieve amounts to about 10%, meaning that a rod of this material could get 10% longer when triggered — enough to do significant work.

One common application of shape-memory materials is relief valves, where if a tank of something exceeds a certain critical temperature, the valve is triggered by that heat, automatically opening to relieve pressure and prevent explosion. The new ceramic material could now extend that capability to far higher-temperature situations than present materials can handle.

For example, actuators that direct airflow inside a jet engine might be a useful application, Pang says. While the overall environment there is hot, there are various channels of airflow being controlled, so those flows could be used to trigger a shape-memory ceramic by directing cooler or hotter air on the device as needed.

Today, shape-memory ceramics that exist “are sort of a laboratory curiosity” because they fall apart after a few cycles, Schuh says. “This is a step in the direction of making something that can reproducibly and reliably operate many, many times in service.”

The team plans to continue exploring the material, finding ways to produce it in bigger batches and more complex shapes, and testing its ability to withstand many cycles of transformation.

What attracted Schuh to this project in the first place is its potential for broad applications. “There are things we do with complex mechanical systems that have lots of parts and assemblies, and the idea that you can replace a complicated package of things with a single material that has the functionality built-in at the atomic scale — to me, that’s attractive because it makes large, complicated things into small, simple things. In some ways it’s like replacing vacuum tubes with transistors.”

While it’s hard to predict the areas where this material will find its first practical uses, Schuh says that, for example, “it’s very hard to scale down a hydraulic piston. It’s hard to make that on the micro scale.” But now, “the idea that you have a solid-state version of that at very small scales – I’ve always felt there are a lot of applications for microscale motions. Microrobots in small places, lab-on-a-chip valves, lots of small things that need actuation could benefit from smart materials like this.”

This story is adapted from material from MIT, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.