Adoption of powder-in-tube method to fabricate superconducting wire can realize a large application of Nb3Al prepared by powder metallurgy. Powder metallurgy was used to synthesize Nb3Al under various heat-treatment conditions, annealing temperature was varied from 700 to1,000 °C and heating time was varied from 10 to 50 h.X-ray diffraction patterns reveal that a reaction between Nb and Al took place and formed NbAl3phase. Under current heat-treatment conditions(annealing temperature was varied from 700 to 1,000 °C and heating time was varied from 10 to 50 h), NbAl3was so stable that it did not further react with the unreacted Nb and was not sensitive to the heat-treatment condition. By mechanical alloying, adoption of high-energy ball milling significantly decreases particle size and enhances surface free energy, which promotes the formation of Nb3Al phase. X-ray diffraction patterns indicate that relatively pure Nb3Al phase was obtained under the same heat-treatment condition. Energy-dispersive X-ray analysis measurement demonstrates that the obtained samples were close to the right stoichiometry of A15 structure Nb3Al. Adoption of powder-in-tube method to fabricate superconducting wire can realize a large application of Nb3Al prepared by powder metallurgy. Powder metallurgy was used to synthesize Nb3Al under various heat-treatment conditions, annealing temperature was varied from 700 to 1,000 ° C and heating time was varied from 10 to 50 hX-ray diffraction patterns reveal that a reaction between Nb and Al took place and formed NbAl3phase. Under current heat-treatment conditions (annealing temperature was varied from 700 to 1,000 ° C and heating time was varied from 10 to 50 h), NbAl3was so stable that it did not react with the unreacted Nb and was not sensitive to the heat-treatment condition. By mechanical alloying, adoption of high-energy ball-milling greatly decreasing particle size and enhances surface free energy , which promotes the formation of Nb3Al phase. X-ray diffraction patterns indicate that relatively pure Nb3Al phase was obtained under the same heat-treatment condition. Ener gy-dispersive X-ray analysis measurement demonstrated that the obtained samples were close to the right stoichiometry of A15 structure Nb3Al.