Nişantaşı University

INVESTIGATION OF INDENTATION FRACTURE TOUGHNESS (K-IC) AND WEIBULL PARAMETERS OF 0.25Li(2)O.2SiO(2)-0.75BaO.2SiO(2) GLASS-CERAMIC

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dc.contributor.author Ertuğ, Burcu
dc.contributor.author Çetiner, Burcu Nilgün
dc.contributor.author Gökçe, Hasan
dc.contributor.author Erkmen, Ziya Engin
dc.contributor.author Öveçoğlu, Mustafa Lütfi
dc.date.accessioned 2019-06-25T10:41:32Z
dc.date.available 2019-06-25T10:41:32Z
dc.date.issued 2017-12
dc.identifier.issn 1733-3490
dc.identifier.uri http://hdl.handle.net/20.500.12474/53
dc.description.abstract Fracture of ceramics in general starts from flaws, which are spread throughout. The higher the load, the larger the probability of the failure. Also, the failure probability changes with the sample size. According to Griffith/Irwin equation, when stress intensity factor K = s.Y(p.a)–1/2 exceeds the fracture toughness, KIC one can estimate the formation of critical flaws. This equation shows the relationship between the flaw size and critical load [1]. Weibull modulus (m) is widely used to evaluate the structural reliability of the material. The higher the Weibull modulus, the higher the structural reliability [2]. For technical ceramics, the value of the Weibull modulus is between 5 and 20 [3]. The probability of failure changes with distribution of the weak stress regions. Over these weak stress regions, the crack starts and propagates. These regions are related to the fracture toughness of the material. Thus the Weibull statistics and fracture toughness are closely related [4]. Ceramics in general, possess higher hardnesses than metallic materials. However, they indicate poor toughness and low strength reliability. Low Weibull moduli show highly variable crack length in the material exhibiting broad strength distribution [5]. If the type of the distribution function is known, the number of experiments can be reduced, because only a few parameters and not the distribution function in each detail must be determined. In the case of the Gaussian and Poisson distributions, the parameters are the mean value and the standard deviation. For the Weibull distribution, the parameters are the characteristic strength and the Weibull modulus [6]. In the present paper, it was attempted to characterize a novel glass-ceramic composition. Main properties such as Vickers microhardness and indentation fracture toughness were examined. In addition, structural reliability of the samples was evaluated using Weibull parameters derived from the experimental results. tr_TR
dc.language.iso en tr_TR
dc.publisher ARCHIVES OF METALLURGY AND MATERIALS tr_TR
dc.subject Lithium barium silicate glass-ceramic tr_TR
dc.subject Indentation Fracture Toughness tr_TR
dc.subject Hardness tr_TR
dc.subject Statistical Analysis tr_TR
dc.subject Weibull modulus tr_TR
dc.title INVESTIGATION OF INDENTATION FRACTURE TOUGHNESS (K-IC) AND WEIBULL PARAMETERS OF 0.25Li(2)O.2SiO(2)-0.75BaO.2SiO(2) GLASS-CERAMIC tr_TR
dc.type Article tr_TR


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