Eu-doped MgxZn1-xO hexagonal nanocrystals with wurtzite-type structure were fabricated on quartz substrates by electron beam evaporation using Mg0.15Zn0.85O:Euy(0≤y≤0.08)target combined thermal annealing followed with rapid cooling.The influence of Eu on the microstructure and optical properties of MgxZn1-xO hexagonal nanocrystals had been investigated using X-ray diffraction spectra,X-ray photoelectron energy spectra,scanning electron microscopy,absorption spectra,and photoluminescence spectra.It was found that Eu-doped MgxZn1-xO hexagonal nanocrystals annealed at 700°C exhibited(002)preferred orientation,whereas undoped MgxZn1-xO hexagonal nanocrystals annealed at 700°C did not exhibit preferential growth.The Mg concentration of Eu-doped and undoped MgxZn1-xO hexagonal nanocrystals annealed at 700°C were both 0.08.However,an evident phase separation of the Eu-doped MgxZn1-xO hexagonal nanocrystals with Mg0.08Zn0.92O/Mg0.03Zn0.97O/air SQW core-shell structures was observed.The binding energy of exciton in Mg0.03Zn0.97O(66 meV)was larger than that in Mg0.08Zn0.92O(50 meV)that was further evidence of Mg0.08Zn0.92O/Mg0.03Zn0.97O/air SQW core-shell structures formed. Eu-doped MgxZn1-xO hexagonal nanocrystals with wurtzite-type structure were fabricated on quartz substrates by electron beam evaporation using Mg 0.15Zn 0.85O: Euy (0≤y≤0.08) target combined thermal annealing followed with rapid cooling. The influence of Eu on the microstructure and optical properties of MgxZn1-xO hexagonal nanocrystals had been investigated using X-ray diffraction spectra, X-ray photoelectron energy spectra, scanning electron microscopy, absorption spectra, and photoluminescence spectra. It was found that Eu-doped MgxZn1- xO hexagonal nanocrystals annealed at 700 ° C exhibited (002) preferred orientation, and undoped MgxZn1-xO hexagonal nanocrystals annealed at 700 ° C did not exhibit preferential growth. The Mg concentration of Eu-doped and undoped MgxZn1-xO hexagonal nanocrystals annealed at 700 ° C were both 0.08.However, an evident phase separation of the Eu-doped MgxZn1-xO hexagonal nanocrystals with Mg0.08Zn0.92O / Mg0.03Zn0.97O / air SQW core-shell structures was observed. binding energy of exciton in Mg0.03Zn0.97O (66 meV) was larger than that in Mg0.08Zn0.92O (50 meV) that was further evidence of Mg0.08Zn0.92O / Mg0.03Zn0.97O / air SQW core-shell structures formed.