Effect of the parameters of bimodal microstructure on the mechanical properties of alumina: A case of sintering regime effects

TL;DR

This study investigates how different sintering regimes influence the microstructure and mechanical properties of alumina ceramics, identifying optimal conditions for enhanced strength and toughness.

Contribution

It introduces a detailed analysis of sintering regimes' effects on bimodal microstructure parameters and mechanical properties of alumina ceramics, highlighting optimal sintering conditions.

Findings

Microstructure with large grains and fine matrix enhances mechanical properties.

Sintering regime significantly affects grain size and distribution.

Optimal parameters improve hardness, toughness, and strength.

Abstract

The effect of sintering regimes on the density, microstructure parameters, and mechanical properties of Al2O3 and Al2O3 + 0.25%MgO ceramics has been investigated. The ceramics were sintered in three regimes: Regime I - heating at a constant rate (2.5, 5, 10, 20 C/min) up to the temperature T=1650C; Regime II - heating with a varied heating rate up to 1565C with the duration corresponding to sintering at the heating rate of 10 C/min in Regime I followed by a three-fold decrease in the shrinkage rate; Regime III - two-stage sintering: heating according to Regime II up to the temperature T1+1550C, then lowering the temperature down to T2 = 1300-1500C and holding for 3 h at the T2. The sintering regimes were chosen so that the ceramics had the relative density of 97-99% and a bimodal distribution of the microstructure parameters. The Al2O3 and Al2O3 + 0.25%MgO ceramics obtained in Regimes I-III had a microstructure with abnormally large grains in a fine-grained matrix. The sizes and volume fractions of the large grains depended on the sintering regime. Most abnormally large grains had elongated shapes that leads to deviations in the crack propagation trajectories from the straight line. The optimal parameters of the bimodal microstructure parameters distribution providing enhanced mechanical properties of the ceramics (hardness, indentation fracture toughness, ultimate strength) have been determined.