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A New Window into the Deformation of Nanoscale Materials

 

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Scientists have long assumed that a crystal needs to be perfect to sustain stress at its theoretical limit. Beyond this point dislocations in the crystal lattice occur, and the crystal undergoes a nonreversible change of shape, or plastic deformation.   Now a team from the Department of Energy’s Lawrence Berkeley National Laboratory, Purdue University, and Hysitron Incorporated in Minneapolis has found that things don’t necessarily happen this way. Using special instrumentation with the JEOL 3010 In Situ Transmission Electron Microscope at the National Center for Electron Microscopy (NCEM), the researchers were able to correlate high-resolution load-displacement measurements with individual video frames, showing how nanoscale volumes of aluminum deform under stress from a diamond “nanoindenter.”

“Although it’s been assumed that you need a perfect volume of material to reach the ideal strength, our results show this is not always true,” says Andrew Minor of Berkeley Lab’s Materials Sciences Division, who led the research team. “The situation is more complex. We found that plenty of defects accumulate before the point that would usually be interpreted as the initial yield point.”

And that’s not all, Minor adds. “Surprisingly, even when the material had a high defect density it could withstand near-theoretical shear stresses.”

Team member Zhiwei Shan says, “Ideas about the onset of plasticity during nanoindentation have typically been based on indirect evidence. Computational studies can calculate the ideal strength of a material based on its electronic structure and the bond strengths between the atoms in a perfect crystal. While researchers have tried to correlate these calculated ideal strengths with nanoindentation experiments, until now they’ve had to infer the relationship after the fact, mainly from the strengths achieved.”

The specially equipped in situ transmission electron microscope that revealed the true sequence of events, says Minor, “is an experimental set-up unique in the world” because it combines, for the first time, two distinct ways of looking at the onset of plasticity during nanoindentation, producing images of the deformation events and mechanical data at the same time.

Nanoindentation techniques pioneered at NCEM feature real-time movies, which can be studied frame by frame, taken inside the transmission electron microscope. Another way of studying plasticity is outside the microscope, with sensors that precisely measure the forces imposed by the indenter as the system evolves. “Until now, attempts to correlate deformation events with force measurements have been ex post facto and thus inherently limited,” says Minor.

The research team built a quantitative in situ nanoindenter by integrating a capacitive force sensor from Hysitron into a sample holder designed by NCEM, taking advantage of the in situ microscope’s large sample-stage area. For the first time data and movies documenting nanoscale deformation events could be made simultaneously and directly.

“Most people have the force-versus-displacement graph but not the movie,” says Shan. “On the graph, one big spike marks the ‘pop-in’ event — usually thought of as the onset of plasticity. In movies, the first appearance of defects and displacements was thought to be the pop-in event.”

“As it turns out, these two events don’t necessarily coincide,” says Minor. “In fact there are often faint signals of deformation before the actual pop-in event in many nanoindentation data sets, but these subtleties have often been regarded as noise, or just assumed to be unimportant.”

A typical nanoindentation experiment with the new set-up involves a three-sided diamond indenter approaching the apex of a target grain of aluminum, a single crystal within a thin film of aluminum deposited on a silicon substrate. As the indenter loads the crystal — pressing against it — the load and displacement of the indenter are plotted on a graph. Simultaneously the video shows corresponding changes in the crystal.