Yttria-stabilized tetragonal zirconia polycrystal (Y-TZP) is currently a scientific and clinical research focus in the field of dental materials, owing to its excellent combination of mechanical features, aesthetics and biocompatibility [1]. Generally, zirconia-derived dental prostheses are fabricated using subtractive manufacturing (SM) technology, which applies computer aided design/computer-aided manufacturing (CAD/CAM) systems [2]. However, some problems with this technology have been recorded in recent years; for instance, it not only causes significant waste of materials and tools, but also has limitations in the fabrication of parts with complex geometries [3]. Consequently, additive manufacturing technologies have attracted increasing attention. Stereolithographic methods, including stereolithography and digital light processing (DLP), are promising for producing small and complex dental parts, which require both high accuracy and surface quality. In addition, these techniques significantly reduce the production steps and consumption of energy and raw materials [3,4].Generally, zirconia crystals are found in three structural entities, including the tetragonal and cubic phases at temperatures of >1170 °C and >2370 °C, respectively. The tetragonal phase is stabilized at ambient by yttria addition to generate a Y-TZP ceramic [1,5]. Currently, 3 mol% yttria stabilized Y-TZP (3Y-TZP) is the most commonly used zirconia ceramic in dentistry because of its excellent mechanical properties. However, this material is susceptible to low-temperature degradation (LTD) under moist conditions [1,6]. LTD involves a nucleation and growth process, which generally starts at the surface of polycrystalline ceramics and induces the tetragonal to monoclinic transformation over a temperature range of ~30 °C to 300 °C [6,7]. Furthermore, LTD may affect the biomechanical and surface physicochemical properties and the service life and quality of 3Y-TZPs, particularly for those applied in biomedical settings, which are exposed to complex environments in vivo, such as hip implants and dental restorations [8].
