Abstract
The effect of Al2O3 on non-Newtonian property and structure of mold fluxes was examined with a rotating cylinder method combined with Raman and magic-angle spinning nuclear magnetic resonance technology. Oswald-De Wael'e power-law model was used to quantify the shear-thinning behavior. The results indicated that a shear-thinning behavior formed and first improved and then decreased with increasing Al2O3. The sample with 9.5% Al2O3 revealed the strongest shear-thinning behavior, and its flow behavior index reached a minimum of 0.76. Raman result illustrated the Si-O-Al linkages first became prominent with adding Al2O3, and then depressed with raising shear stresses. 27Al MAS-NMR analysis suggested that AlO4 increased with adding Al2O3. However, AlO4 reduced, AlO3F and AlO5 increased with increasing shear stresses. 29Si MAS-NMR analysis indicated that with increasing shear stress, Q3(1Al) and Q2(1Al) in AlO4 species decreased, and the reduction of Q3(1Al) was larger than that of Q2(1Al), Q2(0Al), Q1, and Q0 units increased.
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