Understanding where and how phase transitions occur is critical to developing new generations of the materials used in high-performance batteries, sensors, energy-harvesting devices, medical diagnostic equipment, and other applications. But until now there was no good way to study and simultaneously map these phenomena at the relevant length scales.
Now, researchers at the Georgia Institute of Technology and Oak Ridge National Laboratory (ORNL) have developed a new nondestructive technique for investigating these material changes by examining the acoustic response at the nanoscale. Information obtained from this technique — which uses electrically-conductive atomic force microscope (AFM) probes — could guide efforts to design materials with enhanced properties at small size scales.
The approach has been used in ferroelectric materials, but could also have applications in ferroelastics, solid protonic acids and materials known as relaxors. Sponsored by the National Science Foundation and the Department of Energy’s Office of Science, the research was reported recently in the journal Advanced Functional Materials.
“We have developed a new characterization technique that allows us to study changes in the crystalline structure and changes in materials behavior at substantially smaller length scales with a relatively simple approach,” said Nazanin Bassiri-Gharb, an associate professor in Georgia Tech’s Woodruff School of Mechanical Engineering. “Knowing where these phase transitions happen and at which length scales can help us design next-generation materials.”
In ferroelectric materials such as PZT (lead zirconate titanate), phase transitions can occur at the boundaries between one crystal type and another, under external stimuli. Properties such as the piezoelectric and dielectric effects can be amplified at the boundaries, which are caused by the multi-element “confused chemistry” of the materials. Determining when these transitions occur can be done in bulk materials using various techniques, and at the smallest scales using an electron microscope.
The researchers realized they could detect these phase transitions using acoustic techniques in samples at size scales between the bulk and tens of atoms. Using band-excitation piezoresponse force microscopy (BE-PFM) techniques developed at ORNL, they analyzed the resulting changes in resonant frequencies to detect phase changes in sample sizes relevant to the material applications. To do that, they applied an electric field to the samples using an AFM tip that had been coated with platinum to make it conductive, and through generation and detection of a band of frequencies.
“We’ve had very good techniques for characterizing these phase changes at the large scale, and we’ve been able to use electron microscopy to figure out almost atomistically where the phase transition occurs, but until this technique was developed, we had nothing in between,” says Bassiri-Gharb. “To influence the structure of these materials through chemical or other means, we really needed to know where the transition breaks down, and at what length scale that occurs. This technique fills a gap in our knowledge.”
The changes the researchers detect acoustically are due to the elastic properties of the materials, so virtually any material with similar changes in elastic properties could be studied in this way. Bassiri-Gharb is interested in ferroelectrics such as PZT, but materials used in fuel cells, batteries, transducers and energy-harvesting devices could also be examined this way.
“This new method will allow for much greater insight into energy-harvesting and energy transduction materials at the relevant length sales,” notes Rama Vasudeven, the first author of the paper and a materials scientist at the Center for Nanophase Materials Sciences, a U.S. Department of Energy user facility at ORNL.
The researchers also modeled the relaxor-ferroelectric materials using thermodynamic methods, which supported the existence of a phase transition and the evolution of a complex domain pattern, in agreement with the experimental results.
Use of the AFM-based technique offers a number of attractive features. Laboratories already using AFM equipment can easily modify it to analyze these materials by adding electronic components and a conductive probe tip, Bassiri-Gharb notes. The AFM equipment can be operated under a range of temperature, electric field and other environmental conditions that are not easily implemented for electron microscope analysis, allowing scientists to study these materials under realistic operating conditions.
“This technique can probe a range of different materials at small scales and under difficult environmental conditions that would be inaccessible otherwise,” says Bassiri-Gharb. “Materials used in energy applications experience these kinds of conditions, and our technique can provide the information we need to engineer materials with enhanced responses.”
Though widely used, relaxor-ferroelectrics and PZT are still not well understood. In relaxor-ferroelectrics, for example, it’s believed that there are pockets of material in phases that differ from the bulk, a distortion that may help confer the material’s attractive properties. Using their technique, the researchers confirmed that the phase transitions can be extremely localized.
They also learned that high responses of the materials occurred at those same locations.
Next steps would include varying the chemical composition of the material to see if those transitions — and enhanced properties — can be controlled. The researchers also plan to examine other materials.
“It turns out that many energy-related materials have electrical transitions, so we think this is going to be very important for studying functional materials in general,” Bassiri-Gharb adds. “The potential for gaining new understanding of these materials and their applications are huge.”
Release Date: December 28, 2015
Source: Georgia Tech