feldspar and yttria

feldspar has been researched along with yttria* in 2 studies

Other Studies

2 other study(ies) available for feldspar and yttria

ArticleYear
Optical properties of base dentin ceramics for all-ceramic restorations.
    Dental materials : official publication of the Academy of Dental Materials, 2011, Volume: 27, Issue:2

    The study was conducted to compare the optical parameters of VM7(®) M-shade base dentin ceramics (VITA, Germany) for all ceramic restorations to the chemical composition across the 3D-MASTER(®) shade system.. Three disc samples, 13 mm diameter and 1.4 mm thickness, were produced for each M-shade following the manufacturer's instructions. Each disc was ground and polished to a thickness of 1.0 mm. Spectral light transmittance and reflectance data were recorded in the visible spectrum under the standard illuminant D65 and 2° observer at 10 nm intervals by using a computer-controlled spectrophotometer. Opacity, translucency and opalescence parameters were determined for each sample.. (1) Spectral transmittance and reflectance in the short-wavelength range systematically decreased with increasing chroma number (M1, M2, M3) when compared within the same value (lightness) group. (2) Spectral transmittance and reflectance decreased systematically across the whole visible spectrum with increasing value group number when compared within the same chroma group. (3) Analysis of relationship between chemical composition and various optical parameters for all the samples showed the significant contribution of ZrO₂ and Y₂O₃ substances to optical properties of the present material.. Systematic variations in optical properties of VM7(®) M-shade base dentin ceramics were observed throughout the 3D-MASTER(®) shade system and were suggested to be caused by the fine structure of the sample which can interfere with shorter wavelengths in the visible spectrum.

    Topics: Absorption; Aluminum Silicates; Ceramics; Color; Dental Polishing; Dental Porcelain; Dental Prosthesis; Dentin; Glass; Humans; Light; Materials Testing; Optical Phenomena; Potassium Compounds; Prosthesis Coloring; Scattering, Radiation; Spectrometry, X-Ray Emission; Tin Compounds; Vanadium Compounds; Yttrium; Zirconium

2011
Lifetime-limiting strength degradation from contact fatigue in dental ceramics.
    Journal of dental research, 2000, Volume: 79, Issue:2

    The hypothesis under examination in this paper is that the lifetimes of dental restorations are limited by the accumulation of contact damage during oral function; and, moreover, that strengths of dental ceramics are significantly lower after multi-cycle loading than after single-cycle loading. Accordingly, indentation damage and associated strength degradation from multi-cycle contacts with spherical indenters in water are evaluated in four dental ceramics: "aesthetic" ceramics-porcelain and micaceous glass-ceramic (MGC), and "structural" ceramics-glass-infiltrated alumina and yttria-stabilized tetragonal zirconia polycrystal (Y-TZP). At large numbers of contact cycles, all materials show an abrupt transition in damage mode, consisting of strongly enhanced damage inside the contact area and attendant initiation of radial cracks outside. This transition in damage mode is not observed in comparative static loading tests, attesting to a strong mechanical component in the fatigue mechanism. Radial cracks, once formed, lead to rapid degradation in strength properties, signaling the end of the useful lifetime of the material. Strength degradation from multi-cycle contacts is examined in the test materials, after indentation at loads from 200 to 3000 N up to 10(6) cycles. Degradation occurs in the porcelain and MGC after approximately 10(4) cycles at loads as low as 200 N; comparable degradation in the alumina and Y-TZP requires loads higher than 500 N, well above the clinically significant range.

    Topics: Aluminum Oxide; Aluminum Silicates; Bite Force; Ceramics; Crystallization; Dental Porcelain; Dental Restoration Wear; Dental Stress Analysis; Glass; Humans; Materials Testing; Potassium Compounds; Stress, Mechanical; Surface Properties; Time Factors; Water; Yttrium; Zirconium

2000