White light-emitting diodes (LEDs) have become a promising luminescent light source in the next generation to substitute for the conventional incandescent and fluorescent lamps. However, the white light produced from the conventional type of white LEDs lacks sufficient emission in the red range, therefore leading to the so-called “cold white light” with a low color rendering index. To overcome the drawback, several alternative approaches have been proposed and been underway now. One of the approaches is to integrate the conventional type of white LEDs with red-emitting phosphors for generating white light with high color rendering index. Another approach is to combine ultraviolet LEDs with tricolor-emitting phosphors, which is also expected to produce the white light with high color rendering index. The above-mentioned alternative approaches are mainly focused in this study. In the first section, nitride-based Sr2Si5N8 was selected as the host material for preparing red-emitting phosphors. Under the blue excitation at 420 nm, solely Eu2+-doped Sr2Si5N8 phosphors displayed a broad emission band peaking at around 615 nm. When Eu2+ and sensitizer ions were co-doped into Sr2Si5N8, it was observed that the emission intensity in the red region tended to increase and was found to be enhanced at most 43% as compared with that of solely Eu2+-doped Sr2Si5N8 phosphor. The results demonstrate that the emission intensity of the phosphors could be enhanced via incorporating Eu2+ and sensitizer ions into Sr2Si5N8, further improving the applicability of the phosphors for white LEDs. In the second section, silicate-based Ca3La6(SiO4)6 was chosen as the host material, while Ce3+ and Tb3+ ions were selected as the doping ions. The solely Ce3+-doped and Tb3+-doped Ca3La6(SiO4)6 phosphors exhibited emissions at 420 nm and 545 nm, respectively. When Ce3+ and Tb3+ ions were co-doped into Ca3La6(SiO4)6, the emission spectra showed a combination of the emission band originated from Ce3+ ions and the emission lines generated from Tb3+ ions. With the increasing doping content of Tb3+ ions, the emission intensity of Ce3+ ions in the blue region decreased monotonically, whereas that of Tb3+ ions in green region considerably increased. The results reveal that the emitting colors of the phosphors could be shifted from purplish blue to green via controlling the doping content of Tb3+ ions. Ca3La6(SiO4)6: Ce3+, Tb3+ phosphors are the prospective color-tunable materials for applications to light emitting diodes.