Phillip Jannotti scite author profile

Photoelastic fringes were directly measured to fully characterize high magnitude, steep compressive stress gradients in an ion-exchanged glass, trade named Ion-Armor™. Initially, using a thick (9.9 mm) rectangular bar and circular polariscope arrangement the overall residual stress profile in a bulk specimen was determined. However, due to the relatively large thickness of the specimen, the high density of fringes (steep stress gradient) close to the edge of the specimen became too diffused to allow an accurate count of fringe order. A thinner (0.71 mm) specimen was then used along with a polarizing light microscope to enhance the fringe contrast. This arrangement yielded approximately four isochromatic fringes, representing a maximum surface compressive stress of 984 MPa, which rapidly decreased to~300 MPa within 25 lm depth from the strengthened surface. Also, the case-depth of the ion-exchange process was found to be 0.8 mm. Thus, the technique was able to directly capture the extremely high residual compressive stresses generated in an ion-exchanged glass. The current technique utilized for residual stress measurement is more objective and straightforward to implement than what is specified in ASTM standard C-1422, particularly for those specimens having steep stress gradients just below the strengthened surface. *subhash@ufl.edu

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Measurement of microscale residual stresses in multi-phase ceramic composites using Raman spectroscopy

Jannotti

Subhash

Zheng

et al. 2017

Acta Materialia

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A methodology is described for characterizing the spatial distribution of thermal mismatch stresses at grain level in B 4 C-SiC-Si ceramic composites using Raman spectroscopy. Unlike traditional methods to detect residual stress (e.g., X-ray diffraction) which provide average values over the entire specimen surface, Raman peak-shift analysis provides residual stress distributions within the microstructure at high spatial resolution. While the classical formulation predicts uniform compressive stress within a Si-phase surrounded by the ceramic matrix, the Raman measurements revealed non-uniform residual stress distributions in Si when the particle size was larger than 5 microns. For large irregular shaped particles, the two methods coincide only along the interface between the particle and matrix, but vary drastically both in magnitude and nature in the interior of the particle where large tensile stresses have been measured. The average residual stress within the microstructure was found to correlate well with the volume fraction of the constituents and material properties. The presence of anomalous tensile stress in the interior of the minor Si-phase results in defect generation and structural disorder which has been confirmed by a subsequent TEM analysis.

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Phillip Jannotti

In search of amorphization-resistant boron carbide

Influence of ultra-high residual compressive stress on the static and dynamic indentation response of a chemically strengthened glass

Photoelastic Measurement of High Stress Profiles in Ion‐Exchanged Glass

Measurement of microscale residual stresses in multi-phase ceramic composites using Raman spectroscopy

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