Abstract

Surface treatment of a silicon nitride (Si3N4) engineering ceramic with fibre laser radiation was conducted
to identify changes in the fracture toughness as measured by K1c. A Vickers macro-hardness indentation
method was adopted to determine the K1c of the Si3N4 before and after fibre laser surface treatment. Optical and a
scanning electron microscopy (SEM), a co-ordinate measuring machine and a focus variation technique were used
to observe and measure the dimensions of the Vickers indentation, the resulting crack lengths, as well as the crack geometry within the as-received and fibre laser-treated Si3N4. Thereafter, computational and analytical methods
were employed to determine the K1c using various empirical equations. The equation K1c = 0.016 (E/Hv)1/2 (P/c3/2)
produced most accurate results in generating K1c values within the range from 4 to 6 MPa m1/2. From this it was
found that the indentation load, hardness, along with the resulting crack lengths in particular, were the most influential
parameters within the K1c equation used. An increase in the near surface hardness of 4% was found with the Si3N4 in comparison with the as-received surface, which meant that the fibre laser-treated surface of the Si3N4 became harder and more brittle, indicating that the surface was more prone to cracking after the fibre laser treatment. Yet, the resulting crack lengths from the Vickers indentation tests were reduced by 37% for the Si3N4 which in turn led to increase in the K1c by 47% in comparison with the as-received surface. It is postulated that the fibre laser treatment induced a compressive stress layer by gaining an increase in the dislocation movement during elevated
temperatures from the fibre laser surface processing. This inherently increased the compressive stress within the
Si3N4 and minimized the crack propagation during the Vickers indentation test, which led to the fibre laser radiated surface of the Si3N4 engineering ceramic to have more resistance to crack propagation.