Ultra-fast, selective, non-melting, laser sintering of alumina with anisotropic and size-suppressed grains

In this paper, we report an ultra-fast sintering phenomenon of alumina achieved by the scanning laser irradiation method. Using CO2 laser irradiation, we found that micrometer-sized alumina powder (d(50) = 1.2 mu m) can be sintered close to full density within a few tens of seconds. The microstructure of laser-sintered alumina was different from that of the furnace-sintered alumina. The relative density and grain size of the laser-sintered alumina gradually decreased from the center of the laser beam to the edge. Anisotropy of the grain size was measured along and perpendicular to the scanning direction. This anisotropy decreased as the scanning speed decreased from 0.1 mm/s to 0.01 mm/s. The sintering master curve of grain size versus relative density, which reflects the sintering mechanism, was found to be affected by the laser scanning speed. When the laser scanning speed was 0.1 mm/s, grain size suppression was found for the almost fully dense alumina. However, at lower scanning speed (e.g., 0.01 mm/s), there was significant grain growth in the regions where the relative density was greater than 90%. These results clearly indicate that alumina can be sintered, in the solid-state, to a high density in a short time using scanning laser and the microstructure is different from the furnace-sintered alumina.

Automated summary

This paper reports an ultra-fast sintering phenomenon of alumina achieved through scanning laser irradiation. The study found that alumina can be sintered to high density in a short time using laser scanning, with a different microstructure compared to furnace-sintered alumina. The grain size and relative density of laser-sintered alumina vary from the center to the edge of the laser beam, and the sintering mechanism is affected by the laser scanning speed.