A new Weizmann Institute of Science ceramic could replace lead-based electronic components.
Produced in the Weizmann lab or Professor Igor Lubomirsky’s this material seems too good to be true. It belongs to a class of materials that are the backbone of many essential technologies which unfortunately also create an environmental problem because they usually contain lead, which is highly toxic. The surprising thing about the Weizmann ceramic is that it can perform just as well as other materials in this category while being entirely nontoxic.
The new material falls into a class of substances that become deformed when exposed to an electric field, undergoing strains and stresses that are widely exploited in a slew of devices to produce tiny, precise movements. In cell phones, for example, the slight deformation induced by voltage can set off the charging process or move the lens to create autofocus. In industrial inkjet printers, a plate buckles when voltage is applied, ejecting a controlled amount of ink.
At present, materials that undergo such deformations – they are known as electrostrictors or piezoelectrics, depending on the underlying mechanism – are a major source of lead pollution. Because electrostrictive and piezoelectric components tend to be too small to be recycled, tons of lead regularly end up in landfills. Even though lead has been phased out from most other applications in the Western world, these materials are so indispensable that their use continues to be permitted. Piezoelectric materials, for example, constitute an annual global market of over $20 billion.
Previous attempts by scientists around the world to produce lead-free electrostrictive or piezoelectric materials have been only marginally successful: Some are too chemically reactive, others too difficult to make.
In contrast, the Weizmann substance – cerium oxide laced with about ten percent zirconium oxide – is inert and simple to manufacture. But perhaps its major potential advantage is that compared to materials currently in use, it can produce the same deformation while having a much lower dielectric constant, which means that it stores less electric charge – that is, it requires less energy to do the same work.
Moreover, the new ceramic’s source materials are cheap and readily available. Both cerium and zirconium are relatively abundant in Earth’s crust and are mined all over the planet for a variety of industrial applications. Cerium oxide, for example, is commonly used in powdered form to polish lenses and as a catalyst in catalytic converters, devices that reduce harmful emissions in cars.
The Weizmann ceramic might therefore offer an attractive and environmentally friendly alternative to existing electrostrictive or piezoelectric materials. But when, over a decade ago, Lubomirsky first started the research that would lead to its discovery, practical applications were far from his mind. His team had discovered that under certain circumstances, the mechanical properties of cerium oxide – in pure form and when laced with impurities – didn’t fit the classical picture. The electrostrictive effect was about 100 times stronger than expected according to the predominant theory – still too tiny to be of practical use, but intriguing. The team continued to explore it.
About three years ago, Maxim Varenik, a PhD student in Lubomirsky’s lab, performed an experiment that produced startling results. He introduced trivalent impurities – atoms with a chemical valence of three, that is, having three electrons in their outer orbit – into cerium. When he applied voltage to the resultant substances, he noticed an interesting, regular phenomenon: The smaller the inserted atoms were in size, the greater the electrostriction. Because the increases in electrostriction had occurred along such a neat, straight line, he was curious to continue experimenting with ever smaller atoms. However, he ultimately ran out of trivalent impurities; none of the smaller ones he had already tried could be dissolved in cerium oxide.
Varenik then decided to introduce zirconium, the substance usually used in catalytic converters, even though it has four electrons in its outer orbit rather than three. To his and everyone else’s amazement, the electrostriction of the material he created didn’t move up by a notch, as had happened with the other experimental materials. Rather, it shot up about two hundredfold.
“For about ten years we’d studied something considered utterly useless – we did it for the sake of scientific curiosity,” Lubomirsky said.
“Now we’ve suddenly obtained a material with potential engineering applications. The strains and stresses produced within it by voltage are on a par with those observed in the best commercial materials.”
In addition to exploring the properties that might make their ceramic attractive for industrial use, scientists in Lubomirsky’s lab are trying to explain why its electrostrictive performance was so far off the classical charts.
“This is not an animal we’ve ever seen in our zoo,” Lubomirsky said.
Ever since discovering this nonclassical electrostriction, Lubomirsky’s team has been studying it in collaboration with Professor Anatoly Frenkel of Stony Brook University, one of the world’s leading experts on a type of spectroscopy known as EXAFS. Recently, they were joined in this research by the theoretician Professor Yue Qi of Brown University. Their task, however, is far from being complete.
“We still don’t fully understand what happens in this material. but that’s precisely what makes it interesting,” Lubomirsky concluded.
Both Frenkel and Qi took part in this study, which was led by Varenik and Dr Boyuan Xu of Brown University, Providence, RI. Study authors also included Junying Li, Elad Gaver, Dr Ellen Wachtel, Dr David Ehre and Sergey Khodorov of Weizmann’s Molecular Chemistry and Materials Science Department; and Dr Prahlad K. Routh of Stony Brook University.
