A comparative transmission electron microscopy, energy dispersive x-ray spectroscopy and spatially resolved micropillar compression study of the yttria partially stabilised zirconia - porcelain interface in dental prosthesis

“…Failure was found to be more likely within the near-interface porcelain at a distance of between 1 − 2 μm from the interface. This length scale correlates well with the position of nanoscale voiding observed in porcelain by Lunt et al [11] (0.4 − 1.5 μm from the interface) suggesting that there may be an underlying structural weakness in the porcelain at this location. The random nature of void type features may also explain the large scatter observed in the fracture toughness of the near-interface porcelain pillars.…”

“…At present the exact origin of this increased toughness is not clear. One explanation may be high elemental composition sensitivity of YPSZ fracture toughness [18,36] and the variations in the concentration of Si, K, Na and Al known to be present within the first 5 μm of the interface [11]. Perhaps more likely, given the scatter in the fracture toughness values obtained, is the grain size dependence of YPSZ fracture toughness [37].…”

“…In order to aid in aligning the indenter on the center of each pillar, a 25 nm deep target cross was milled into the surface, as shown in Figure 1b. High resolution imaging was performed on each pillar in using SEM stage tilt angles of 0° and 35° in order to measure the radius ( ) and height of each pillar using the technique previously outlined by Lunt et al [11]. Precise measurement of the distance from the interface to the center of each pillar was also performed during this process.…”

“…Microanalysis and compositional mapping of the YPSZ-porcelain interface has been performed using a broad range of experimental techniques including Scanning Electron Microscopy (SEM) [10,11], Energy Dispersive Spectroscopy (EDS) [11,12], Transmission Electron Microscopy (TEM) [11,13] and micro-focus X-ray diffraction [10,14]. These studies have demonstrated that the microstructural variation at the YPSZ-porcelain interface is limited to within the first few hundred microns of the interface, and that the behavior is influenced by both nano-voiding and nano-grain features.…”

“…However, these studies do not provide insight into the mechanical properties of most significance for prosthesis integrity: stiffness, hardness (yield strength) and toughness. Recently, microscale spatially resolved studies of Young's modulus and yield strength variation across the YPSZ-porcelain interface region have recently been published [11,15,16]. The analysis of toughness variation at very short length scales has remained an insurmountable challenge, despite the fact that material resistance to crack initiation and propagation, is critical for understanding the origins of the brittle failure observed at the YPSZ-porcelain interface.…”

Microscale resolution fracture toughness profiling at the zirconia-porcelain interface in dental prostheses

“…Failure was found to be more likely within the near-interface porcelain at a distance of between 1 − 2 μm from the interface. This length scale correlates well with the position of nanoscale voiding observed in porcelain by Lunt et al [11] (0.4 − 1.5 μm from the interface) suggesting that there may be an underlying structural weakness in the porcelain at this location. The random nature of void type features may also explain the large scatter observed in the fracture toughness of the near-interface porcelain pillars.…”

“…At present the exact origin of this increased toughness is not clear. One explanation may be high elemental composition sensitivity of YPSZ fracture toughness [18,36] and the variations in the concentration of Si, K, Na and Al known to be present within the first 5 μm of the interface [11]. Perhaps more likely, given the scatter in the fracture toughness values obtained, is the grain size dependence of YPSZ fracture toughness [37].…”

“…In order to aid in aligning the indenter on the center of each pillar, a 25 nm deep target cross was milled into the surface, as shown in Figure 1b. High resolution imaging was performed on each pillar in using SEM stage tilt angles of 0° and 35° in order to measure the radius ( ) and height of each pillar using the technique previously outlined by Lunt et al [11]. Precise measurement of the distance from the interface to the center of each pillar was also performed during this process.…”

“…Microanalysis and compositional mapping of the YPSZ-porcelain interface has been performed using a broad range of experimental techniques including Scanning Electron Microscopy (SEM) [10,11], Energy Dispersive Spectroscopy (EDS) [11,12], Transmission Electron Microscopy (TEM) [11,13] and micro-focus X-ray diffraction [10,14]. These studies have demonstrated that the microstructural variation at the YPSZ-porcelain interface is limited to within the first few hundred microns of the interface, and that the behavior is influenced by both nano-voiding and nano-grain features.…”

“…However, these studies do not provide insight into the mechanical properties of most significance for prosthesis integrity: stiffness, hardness (yield strength) and toughness. Recently, microscale spatially resolved studies of Young's modulus and yield strength variation across the YPSZ-porcelain interface region have recently been published [11,15,16]. The analysis of toughness variation at very short length scales has remained an insurmountable challenge, despite the fact that material resistance to crack initiation and propagation, is critical for understanding the origins of the brittle failure observed at the YPSZ-porcelain interface.…”

Microscale resolution fracture toughness profiling at the zirconia-porcelain interface in dental prostheses

Bibliography

Influence of laminate code and curing process on the stability of square cross-section, composite columns – Experimental and FEM studies