Centimeter-sized Mg_(65)Zn_(30)Ca_5 bulk amorphous alloys were fabricated by the spark plasma sintering process from the amorphous powders with a size smaller than 5 l m prepared by ball-milling.The sintered Mg_(65)Zn_(30)Ca_5samples were in an amorphous state when the spark plasma sintering was performed at a temperature of 383 K under a pressure of 600 MPa.The data of polarization curves presented that the sintered Mg_(65)Zn_(30)Ca_5bulk amorphous alloys exhibited higher corrosion resistance than pure Mg and AZ31B alloy owing to high content of Zn and homogeneous structure.A calcium phosphate compound layer was formed on the sintered Mg_(65)Zn_(30)Ca_5bulk amorphous sample after immersion in Hanks’solution,which is effective in improving corrosion resistance and bioactivity.The sintered Mg Zn Ca bulk amorphous alloys with large dimensions broaden the potential application of bulk amorphous alloys in the biomedical fields. Centimeter-sized Mg_ (65) Zn_ (30) Ca_5 bulk amorphous alloys were fabricated by the spark plasma sintering process from the amorphous powders with a size smaller than 5 μm prepared by ball-milling.The sintered Mg_ (65) Zn_ (30) Ca_5 samples were in an amorphous state when the spark plasma sintering was performed at a temperature of 383 K under a pressure of 600 MPa. The data of polarization curves presented that the sintered Mg_ (65) Zn_ (30) Ca_5bulk amorphous alloys exhibited higher corrosion resistance than pure Mg and AZ31B alloy due to high content of Zn and homogeneous structure. A calcium phosphate compound layer was formed on the sintered Mg_ (65) Zn_ (30) Ca_5bulk amorphous sample after immersion in Hanks’ solution, which is effective in improving corrosion resistance and bioactivity. The sintered Mg Zn Ca bulk amorphous alloys with large dimensions broaden the potential application of bulk amorphous alloys in the biomedical fields.