A team of researchers from the University of Manchester (United Kingdom), the National Institute of Applied Sciences in Lyon (France) and the ESRF has revealed how a growing crack interacts with the 3D crystal structure of stainless steel. By using a new grain mapping technique it was possible to determine the internal 3D structure of the material without destroying the sample. Afterwards, a crack was initiated in the stainless steel, and the scientists were able to study how the crack grew between the grains. This is the first time that such an experiment has used the 3D grain mapping technique, and the first results are published in the journal Science this week.
Sample surface with cracks colored red.
(Photo Credit: Andrew King.)
Cracks can appear in stainless steel components when stress or strain is combined with a corrosive environment that attacks sensitive grain boundaries. These cracks represent a critical failure mechanism. In power generation plants, certain grain boundaries can become sensitive during heat treatments or during fast neutron irradiation in nuclear power stations.
Most metals used for engineering are made up of many small crystals or grains. The scientists used a new technique called diffraction contrast tomography, developed at the ESRF, to obtain a 3D map of all grains in a section of a stainless steel wire measuring 0.4 mm in diameter. This map contained the shapes, positions, and orientations of 362 different grains. The next stage of the experiment involved putting the wire into a suitable corrosive liquid, and applying a load to cause microcracks to grow between grains. During the crack growth, 3D tomographic scans (of 30 minutes each) were made at intervals of between two hours and a few minutes to follow the progress of the crack. This is the first in-situ experiment of this kind to use non-destructive 3D grain mapping techniques.
Sample and cracks.
(Photo Credit: Andrew King.)
"The cracks grew along the boundaries between the grains which we had mapped in 3D, and we could visualize both the growing crack and certain special boundaries that resist cracking", explains Andrew King, corresponding author of the paper in Science. "Some of these resistant boundaries were not the ones that we expected".
The special, crack-resistant boundaries may be of key importance to the metallurgy industry. Materials containing more of these boundaries are also more resistant to this type of cracking. Being able to study crack growth in-situ will allow scientists to understand what types of grain structures will give the best performing materials, leading, for example, to more efficient and safer power plants, and more generally to more lightweight alloys in other sectors of metallurgy and engineering.
Source: European Synchrotron Radiation Facility
Grain map with crack superimposed, showing crack following grain boundaries.
(Photo Credit: Andrew King)