earth (RE) ion-doped materials have been developed as significant gain matrices due to their high photoluminescence quantum yield (PLQY) and multiple-wavelength luminescence. [4,5] Recent decades have witnessed extensive investigations in doping methods and network structure design to obtain more efficient gain materials. [6,7] However, the requirements for high luminescence efficiency and excellent thermodynamic stability of optical materials are always contradictory, greatly restricting their applications in, e.g., high-temperature, high-humidity, and high-power laser pumping environments. Generally, the luminescence efficiency of an optical material is inversely proportional to the multiphonon nonradiative transition probability (W p ) of the intermediate state energy level for RE ions. [8] The luminescence process, especially for the upconversion (UC) process, is normally associated with a large number of intermediate state energy levels. Furthermore, its value (W p ) depends on the maximum phonon energy (ћω) of the elastic structure of condensed matter, and it increases dramatically with increasing ћω (as described in Equations (S1)-(S3) of the Supporting Information). [9] Traditionally, one class of soft material with extremely low ћω values, including fluorides, chalcogenides, and halogenides, has been widely Optical gain materials are of fundamental importance for various applications, such as lasers, lighting, optical communication, microscopy, and spectroscopy. However, the requirements for high luminescence efficiency and excellent thermodynamic stability of materials are always contradictory. As a result, wide applications of optical materials in high-temperature, high-humidity, and high-power laser-irradiated environments are restricted. Here, a facile approach based on phase-separation engineering is proposed to modulate the thermodynamic stability and enhance the luminescence efficiency of optical gain materials. It is shown that the thermodynamic stability and luminescence efficiency of the phase-separated fluorosilicate (FS) gain glass are both enhanced dramatically when the SiO 2 concentration is optimized. Owing to the confinement effect of phase-separation network structure on active ions, the upconversion (UC) luminescence efficiency of the designed glass is 150 times higher than that of traditional FS glasses and even seven times higher than that of ZBLAN (ZrF 4 -BaF 2 -LaF 3 -AlF 3 -NaF) glass, which is the most commonly used material for UC fiber lasing applications. These intriguing properties of the glass indicate that phase-separation engineering not only provides a powerful solution to conquer the conventional contradiction between thermodynamic stability and luminescence efficiency but also offers significant opportunities for manufacturing a wide range of optical composites with multiple functions.