Researchers from Montanuniversität Leoben in Austria and the Fraunhofer Institute for Ceramic Technologies and Systems (Fraunhofer IKTS) in Germany have published a detailed study identifying and classifying strength-limiting defects in additively manufactured ceramics. Titled "Strength limiting defects in additively manufactured ceramics" and published via Open Ceramics, the paper provides a comprehensive classification system for describing defects across major ceramic 3D printing processes, including vat photopolymerization (VPP), material jetting (MJT), and material extrusion (MEX). The research was led by Maximilian Staudacher of Montanuniversität Leoben, in collaboration with Tanja Lube, Eric Schwarzer-Fischer, Johannes Abel, and colleagues from Fraunhofer IKTS in Dresden.
Ceramic additive manufacturing (CAM) allows the fabrication of complex geometries, internal channels, and high-strength components for aerospace, mechanical, and biomedical applications. Despite these advantages, parts produced through VPP, MJT, or MEX frequently exhibit lower mechanical strength and inferior surface quality compared to conventionally processed ceramics. The discrepancy is largely caused by microscopic irregularities -- such as pores, delamination, and inclusions -- that originate during fabrication.
In this study, the authors distinguish between "flaws," small-scale irregularities that are unavoidable in brittle materials, and "defects," process-induced imperfections that significantly reduce strength. Their classification system links defect types to each stage of fabrication, from slicing and feedstock preparation to cleaning and handling. The team manufactured test specimens using a CeraFab 8500 3D printer from Austrian ceramic 3D printing specialist Lithoz GmbH, alongside modified Prusa i3 MK3S+ print heads from Czech manufacturer Prusa Research, and a Multi Material Jetting (MMJ) system developed by AMAREA Technology GmbH, a Dresden-based additive manufacturing company.
All specimens were produced and sintered at Fraunhofer IKTS, a research institute focused on advanced ceramics and system integration, while fracture testing was carried out at Montanuniversität Leoben using four-point bending setups. The combination of microscopy, scanning electron analysis, and fractography enabled precise identification of defect morphology and origin.
Across all examined methods, pores, agglomerates, weak layer adhesion, and delamination emerged as recurring strength-limiting defects. In vat photopolymerization, improper exposure parameters and insufficient slurry height led to "wormhole" defects -- elongated pores propagating across multiple layers. Excessive cleaning using ethanol or ultrasonic baths caused surface flaking and partial dissolution of green bodies. In material jetting, nozzle clogging and inconsistent droplet formation created voids and surface stress concentrations, while edge defects and geometric transitions between perimeter and infill contributed to early failure.
Material extrusion presented a different defect profile, dominated by voids between deposited strands and poor interlayer bonding. Uneven extrusion rates produced under- and over-extruded regions, while high nozzle wear introduced metallic inclusions and dimensional inaccuracies. Vertical build orientations were especially prone to delamination, with bending tests showing up to 50% strength reduction compared to horizontally printed specimens due to stresses acting perpendicular to layer interfaces.
According to the authors, fracture origins could generally be traced back to a combination of pore morphology, surface topography, and loading orientation. "While the starting powders of ceramics produced through AM can be identical, each method introduces a characteristic defect distribution in the final part," the researchers wrote. "Their strength distributions are therefore distinct, and they cannot be considered the same material from a component-design point of view."
Fractography proved to be a particularly effective diagnostic tool for failure analysis, offering insights into defect formation mechanisms without the high cost of non-destructive imaging. Although computed tomography and in-situ inspection techniques continue to improve, the study concludes that resolution limits still prevent reliable detection of smaller but critical defects in dense ceramics.
Fraunhofer IKTS has been a leading center for lithography-based ceramic manufacturing (LCM) and Multi Material Jetting (MMJ), both of which enable high-precision ceramic components for industrial applications. Earlier IKTS studies confirmed the feasibility of multi-material ceramic printing but also highlighted challenges in achieving full density and strong interlayer bonding.
Montanuniversität Leoben's Department of Materials Science has advanced the mechanical characterization of 3D printed ceramics, linking fracture strength to microstructural irregularities. Building on this foundation, the present study introduces a standardized nomenclature to improve cross-comparability among research groups and support emerging standards such as EN ISO/ASTM 52900:2021 and VDI 3405 for additive manufacturing.
The authors propose a taxonomy that groups defects by their process origin: slicing, feedstock preparation, layer formation, shaping, cleaning, handling, contamination, equipment wear, and environmental factors such as humidity and temperature. Each source introduces characteristic defects, from surface aliasing and interlaminar voids to delamination and contamination-induced inclusions.
By mapping these relationships, the study establishes a basis for systematic process optimization. Researchers argue that identifying defects early in the green body -- before sintering -- can guide refinements in printing parameters, material formulation, and handling protocols. Although complete elimination of defects is impossible due to ceramics' inherent brittleness, controlling their size and distribution is essential for improving reliability. The authors suggest combining fractographic data with machine learning and in-situ monitoring in future work to predict defect formation during manufacturing.
The findings show that process-induced defects are intrinsic to additive manufacturing, with each method producing a distinct pattern of microstructural weaknesses that shape part performance. By systematically classifying these defects, the study lays the groundwork for quantitative strength modeling and defect-aware component design.
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