α’-Sr2SiO4 :Eu2+ phase always coexists with the Sr3SiO5:Eu2+ phase when it is synthesized by a high-temperature solid-state method. This may affect the luminescent properties of the Sr3SiO5:Eu2+ phosphors. We investigated the decomposition reaction of Sr3SiO5 during the cooling process with the quenching method. The results indicated that Sr3SiO5 was a stable compound above 1250 ℃. The Sr3SiO5 phase decomposed into α’-Sr2SiO4 and SrO below 1250℃. The α’-Sr2SiO4 :Eu2+ phase would coexist with the Sr3SiO5:Eu2+ phase because of the decomposition reaction of Sr3SiO5 , making the luminescent wavelength of coexistence sample move to the short-wavelength compared with the luminescent wavelength of Sr3SiO5:Eu2+. Pure phase Sr3SiO5:Eu2+ could be obtained by the rapid cooling method to suppress Sr3SiO5 decomposition. When the cooling rate was 20℃/min, nearly pure phase Sr3SiO5:Eu2+ could be produced. α’-Sr2SiO4: Eu2 + phase always coexists with the Sr3SiO5: Eu2 + phase when it is synthesized by a high-temperature solid-state method. This may affect the luminescent properties of the Sr3SiO5: Eu2 + phosphors. We investigated the decomposition reaction of Sr3SiO5 during The cooling process with the quenching method. The results indicate that Sr3SiO5 was a stable compound above 1250 ° C. The Sr3SiO5 phase decomposed into α’-Sr2SiO4 and SrO below 1250 ° C. The α’-Sr2SiO4: Eu2 + phase would coexist with the Sr3SiO5: Eu2 + phase because of the decomposition reaction of Sr3SiO5, making the luminescent wavelength of coexistence sample move to the short-wavelength compared with the luminescent wavelength of Sr3SiO5: Eu2 +. Pure phase Sr3SiO5: Eu2 + could be obtained by the rapid cooling method to suppress Sr3SiO5 decomposition When the cooling rate was 20 ° C / min, nearly pure phase Sr3SiO5: Eu2 + could be produced.