We present a rapid microwave-assisted approach for the preparation of Eu2+-doped orthosilicate phosphors. The preparation method relies on a citrate based sol–gel reaction with subsequent combustion in a domestic microwave oven, in contrast to more conventional solid-state methods. This sol–gel pathway yields phase pure, high quality orthosilicates, in less than 25 min of final heating time. In addition, superior morphology control is achieved employing the sol–gel method compared to solid-state preparations. In order to understand the formation process of the final products, thermogravimetric analyses and temperature-dependent X-ray diffraction data were acquired and compared to the conventional solid-state preparation. The morphology and elemental composition of the obtained luminescent materials were investigated using scanning electron microscopy and energy-dispersive X-ray spectroscopy. The optical properties were elucidated by measuring room-temperature emission and excitation spectra, and the application and efficiency of the obtained phosphors in LED devices was studied.

We report the preparation of calcium oxide (CaO)-based sorbents by ultrasonic spray pyrolysis (USP) with both experimental results and modeling of the sorption process. To mitigate CaO deactivation during carbonation/regeneration cycles, metal oxides with high melting temperatures were dispersed into CaO particles in this bottom-up synthetic method (USP), and their performance was experimentally characterized and evaluated over 50 cycles. The performance of synthesized sorbents was then compared to those expected from an unreacted shrinking core model. The model was able to predict the experimental results and provide an explanation for the effect of sintering and agglomeration on the performance of the sorbents through a variable effective diffusivity. Moreover, it was used to extrapolate sorbent performance over large numbers of cycles.