ﻓﺮﻉ ﺍﻟﺴﻴﺮﺍﻣﻴﻚ ﻭﻣﻮﺍﺩ ﺍﻟﺒﻨﺎﺀ/ﺍﻟﻤﺮﺣﻠﺔ ﺍﻟﺮﺍﺑﻌﺔ Advanced Ceramic 1-1.3 Zirconia Zirconium dioxide (ZrO2, zirconia) is principally derived from zircon, ZrSiO4, which occurs in igneous rocks such as granites and pegmatites. Decomposed pegmatites have been worked for zircon in Madagascar and Brazil. Zircon is also a constituent of some metamorphic rocks and also occurs as secondary deposits in beach sands in Australia, Brazil, India, and Florida. In these secondary deposits, which have been worked commercially, the zircon occurs together with other minerals such as ilmentite, rutile, and monazite. Zirconia is an oxide with very high melting temperature (T ≈ 2,880°C), which solidifies in cubic phase (ZrO2-c, group space Fm 3m), then transforms (T < ≈ 2,370°C) to tetragonal phase (ZrO2-t, P42/nmc) and finally, below ≈ 1,170°C, becomes monoclinical (ZrO2-m, P21/c). This last transition t→m is accompanied by considerable dimensional variations (shear strains of ≈ 0.16 and increase in volume of ≈ 4%), which largely exceed the maximum stress limit, resulting in a fragmentation of the material. A zirconia part sintered at temperatures that the refractarity of this oxide requires – let us say sintered at about 1,500°C – breaks up and is destroyed during cooling, during the t→m transition. This means that “pure” zirconia can be used only in powder form (for example, as starting product for the manufacture of ceramic enamels), and therefore for uses that do not require consolidation into a massive part. There are a number of commercial approaches to producing pure zirconia from zircon. Zircon dissociates above 1750oC into ZrO2 and SiO2. Injection of zircon sand into a plasma (at temperatures >6000oC) results in dissociation and melting. The zirconia solidifies first, in the form of dendrites, and the silica solidifies as a glassy coating on the zirconia. The silica may be removed by leaching in boiling sodium hydroxide solution. The residue is washed and the zirconia is removed by centrifuging. The main production method for zirconium oxide is electric arc melting of zircon between 2100 and 2300oC. Dissociation still occurs at these lower temperatures, but solid zirconia is produced along with liquid silica. The purity of the ZrO2 produced is about 99%. 1 ﻓﺮﻉ ﺍﻟﺴﻴﺮﺍﻣﻴﻚ ﻭﻣﻮﺍﺩ ﺍﻟﺒﻨﺎﺀ/ﺍﻟﻤﺮﺣﻠﺔ ﺍﻟﺮﺍﺑﻌﺔ Advanced Ceramic Another, although commercially less significant, source of zirconia is baddeleyite (impure monoclinic ZrO2). Baddeleyite is found in small deposits and usually contains contaminants such as silica, iron oxide, and Titania. Baddeleyite deposits are mined commercially in Brazil and South Africa. Zirconium ores all contain varying amounts of hafnium, typically 1.5 – 3 wt% of the Zr content. As a result of the chemical similarity of Hf to Zr, separation techniques are expensive. Unless specifically required separation is not performed and technical grade zirconia is sold containing up to 3 wt% Hf. To produce zirconia sintered pieces, ZrO2 must be combined with other oxides known as “stabilizers” (MxOy= primarily CaO, MgO or Y2O3): the ZrO2 MxOy phase diagram is then modified favorably, which helps preserve (at the stable state or metastable state) a “stabilized zirconia”, free from transitions in the entire useful temperature range – in practice from the sintering temperature to room temperature. In the ZrO2-CaO diagram, for example, it is observed that for 20 mol% CaO, the material remains in cubic phase from room temperature to practically the melting temperature. Among the uses of stabilized zirconia, denoted “SZ”, we can mention four main fields: – The production of monocrystals for jewelry, because the optical properties of zirconia is not very different from those of a diamond, at an incomparably lower cost. – The manufacture of crucibles and other refractory parts, because of the high melting temperature and good resistance to corrosive mediums, including molten glass (refractories of A-Z-S system: Al2O3-ZrO2-SiO2); – The manufacture of thermal barriers, for example deposited by plasma spraying using plasma torches for the internal protection of the combustion chamber of jet engines, because the thermal conductivity of zirconia is one of lowest ever known among non-metallic inorganic solids (k ≈ 1 W.m-1.K-1, i.e. 30 times lower than alumina). – The manufacture of ionic conductors. We must mention it here because it is related to the same mechanism of “stabilization”. ZrO2-c has a fluorite structure 2 ﻓﺮﻉ ﺍﻟﺴﻴﺮﺍﻣﻴﻚ ﻭﻣﻮﺍﺩ ﺍﻟﺒﻨﺎﺀ/ﺍﻟﻤﺮﺣﻠﺔ ﺍﻟﺮﺍﺑﻌﺔ Advanced Ceramic (like, for example, UO2), with the zirconium atoms at the nodes of a facecentered cubic lattice and the oxygen atoms occupying all the tetrahedral interstices of this lattice (four nodes for a CFC array and eight tetrahedral sites per array give the stoichiometry ZrO2). The unit is very compact and we can say that the transitions that occur when we cool ZrO2-c come from the need to decompress the structure. However, the introduction of bivalent (CaO and MgO) or trivalent (Y2O3) metal oxides that are used as stabilizers requires, for the charges to be balanced, that the substitution of Zr4+ by M2+ or M3+ is compensated by the presence either of interstitial cations or anionic vacancies. It is the second case that occurs here: a usual SZ, 20% CaO-80% ZrO2 (in moles), therefore contains a 20% deficit of oxygen atoms: Zr1-xCaxO2-xVOx, in KrِgerVink notation, where VO represents oxygen vacancies and x is equal to 0.2. The anionic sublattice is thus decompressed and this considerable concentration in vacancies – more than ten orders of magnitude higher than the normal concentration of defects in thermodynamic equilibrium – allows a considerable mobility of residual oxygen ions, since we know that the diffusion proceeds primarily by a vacancy mechanism, like a puzzle. By virtue of these constitutional oxygen vacancies, the stabilized zirconia offers properties of ionic conduction that allow its application as solid electrolyte, particularly in oxygen sensors and in solid oxide fuel cells. ●Ceramic steel? SZ has rather modest mechanical properties, significantly less remarkable compared to alumina which, associated with higher density, and higher thermal expansion (consequently greater sensitivity to thermal shocks) and markedly increased costs explain why these stabilized zirconias a priori do not have a mechanical application. It is partially stabilized zirconia (PSZ) that have justified the resounding article (“Ceramic steel?”) published in 1975 by Garvie et al. The title suggests that a ceramic can exhibit the high mechanical performances associated with steel, but also that toughening mechanisms recall those used by steel manufacturers. The 3 ﻓﺮﻉ ﺍﻟﺴﻴﺮﺍﻣﻴﻚ ﻭﻣﻮﺍﺩ ﺍﻟﺒﻨﺎﺀ/ﺍﻟﻤﺮﺣﻠﺔ ﺍﻟﺮﺍﺑﻌﺔ Advanced Ceramic t→m transformation of zirconia is a martensitic transformation, in analogy with the transformation used to obtain martensite in tempered steels, and the role of microstructural parameters in ZrO2 is similar to what is observed in metals. The mechanical properties of zirconia with high mechanical performances – of which there are multiple varieties – constitute one of the themes that have inspired the greatest number of publications in the field of ceramics. [HAN 00] constitutes an excellent study on the subject. Figure 1.4 ZrO2-MgO and ZrO2-Y2O3 diagrams; the hatched zones show Compositions normally chosen for ceramics with TT effect [HAN 00] Let us start by analyzing what it is about, by reasoning at room temperature. Anon-stabilized zirconia (Z) is subjected, during its cooling from its processing temperature, to destructive phase transition t→m: its mechanical performances are therefore almost zero. A stabilized zirconia (SZ) is free from these transitions; it remains in general in cubic phase: its mechanical performances are modest. Lastly a partially stabilized zirconia (PSZ) can be made up of a matrix rich in stabilizers, therefore in the form of SZ, within which there is a dispersion of small precipitates of zirconia poor in stabilizers, which should be in monoclinic form but can subsist in a metastable state in tetragonal form. The propagation of a microscopic crack relaxes the stresses applied by the matrix on these precipitates, which enables them to switch to the monoclinic, stable state. 4 ﻓﺮﻉ ﺍﻟﺴﻴﺮﺍﻣﻴﻚ ﻭﻣﻮﺍﺩ ﺍﻟﺒﻨﺎﺀ/ﺍﻟﻤﺮﺣﻠﺔ ﺍﻟﺮﺍﺑﻌﺔ Advanced Ceramic Hence, local swelling (increase in volume of ≈ 4% associated with the t→m transformation) which “clamps” the crack and stops its propagation: we can thus considerably increase mechanical strength and toughness. However simplistic this explanation might be, it highlights the two essential points: i) The t→m transformation, previously considered as a drawback, can become an advantage; ii) The control of microstructural characteristics (for instance, grain size) is essential. Figure 1-4 shows the ZrO2-CaO and ZrO2-Y2O3 phase diagrams, where the main PSZ materials are located. 1-1.4 Rutile Rutile (TiO2, Titania) occurs as a constituent of igneous rocks such as granites and also in metamorphic derivatives such as gneiss. It also occurs as fine needles in slates, biotite mica, quartz, and feldspar. Economically the most important deposits are segregations in igneous rocks as found in Virginia, Canada, and Norway. Rutile is also an important constituent of beach sands resulting from denudation of rutile-bearing rocks, as in Australia, Florida, and India. Titania is also produced by reacting ilmenite FeTiO3 with sulfuric acid at 150–180oC to form titanyl sulfate, TiOSO4: FeTiO3 (s) + 2H2SO4 (aq) + 5H2O (l) → FeSO4 ・ 7H2O (s) + TiOSO4 (aq) Titanyl sulfate is soluble in water and can be separated from undissolved impurities and the precipitated iron sulfate by filtration. Hydrolyzing at 90oC causes the hydroxide TiO (OH) 2 to precipitate: TiOSO4 (aq) + 2H2O (l) → TiO (OH) 2 (s) + H2SO4 (aq) The titanyl hydroxide is calcined at about 1000oC to produce Titania TiO2. 5