Influence of x-irradiation on indentation size effect and formation of cracks for [Ky(NH4)1-y]2ZnCl4 mixed crystals

Abstract

The effects of x‐beam irradiation with different doses on microhardness and its related physical constants on [K~y~(NH~4~)~1‐y~]~2~ZnCl~4~ mixed crystals with concentrations, y equals 0.000, 0.232, 0.644, 0.859 or 1.000 has been studied. The tests were performed for x‐doses from 0.2 kGy up to 1.6 kGy for loads from 20 to 160 g. The variation of hardness on (010) faces of orthorhombic [K~y~(NH~4~)~1‐y~]~2~ZnCl~4~ mixed crystals with load were studied. The experimental results showed that, the hardness decreased as the x‐doses increased. Variation of the microhardness follows the normal ISE trend for low x‐doses and un‐irradiated crystals, then follows the reverse ISE trend for high x‐doses. Analysis of the experimental results revealed that: the radial cracks length, indentation size and applied indentation load are mutually related, and these dependences related with fracture mechanics are the basis of Meyer's empirical law. Indentation size effect (ISE) can be explained satisfactory by Hays‐Kendall's approach and proportional specimen resistance model. Brittleness of two cracks system are applicable for characterizing cracks around indentation impression (i.e. radial cracks) and another is (lateral cracks) for [K~y~(NH~4~)~1‐y~]~2~ZnCl~4~ mixed crystals, crystals in the load range 60 – 160 g. It is shown that indentation induced microhardness decreases, whereas the length of radial cracks induced on indentation increases with the increase of x‐doses. (© 2007 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)