Push-out tests were performed on SiC-SiC fiber composites with single-and multi-layered pyrolytic carbon fibermatrix interphases. It is shown that experimental scatter is significant and a large number of tests is necessary in order to obtain statistically relevant values of interfacial shear strength. A difference between different regions of an individual fiber tow is observed, linked to a local porosity. It is shown that interfacial debonding occurs along the boundary between the fiber and the first carbon layer, regardless of the structure of the interphase, and thus interfacial shear strength is not directly linked to the structure of the interphase.
KeywordsCeramic matrix composites (CMC); interfaces; push-out testing.Silicon carbide (SiC) attracts considerable interest as a candidate material for aerospace [1] and nuclear [2,3] applications due to its high temperature strength, creep resistance [4], oxidation resistance [5], and radiation tolerance [6]. In particular, it is considered for its use in aero-engines [7,8,9] and novel accident-tolerant core (ATC) and accident-tolerant fuel (ATF) concepts [10]. In order to overcome its inherent brittleness [11], while retaining beneficial chemical and nuclear properties, it is suggested to be used in the form of a continuous SiC fiberreinforced SiC matrix (SiC-SiC) composite [12].Pseudo-ductile behaviour is introduced via crack deflections and crack bridging, which occur at fiber-matrix interphase [13,14]. Therefore, the fracture properties of a composite are largely determined by the properties of its interphase, which needs to have low-toughness (promoting crack deflection), and high sliding friction coefficient (increasing energy absorption during fiber sliding) [15,16,17]. Various methods have been suggested for the characterization of these interphases, including micropillar compression [18], microcantilever fracture [19], fiber pull-out [20,21] and fiber push-out [22]. These methods determine different interfacial parameters, but in terms of experimental methodology they can be divided into two major groups -the ones that require manufacturing of each individual micro-specimen prior to testing (micropillar, microcantilever and pull-out testing) and the ones that allow for multiple tests on multiple fibers using a single prepared sample, thus potentially providing much higher number of tests and much better statistics (fiber push-out).Push-out is a well-established method for measuring the interfacial properties. In this method, a thin sample (typically in the range of 50 -100 µm) is manufactured in which the fibers are running in the direction as close to normal to the surface as possible. Load is applied to an individual fiber using a nanoindenter, until debonding occurs and the fiber is displaced. The technique provides the values of interfacial shear strength (ISS) and interfacial sliding friction coefficient.Push-out testing is conceptually a rather simple technique. However, a review of the available literature indicates that there exist several commo...
