The phase constitution, microstructure, electrochemical properties, and lithiation mechanism of the melt-spun Al88-XSi12MnX (X = 1, 3, 5, 7, 10, 13, 15, mol%) ribbons were investigated as anode materials for lithium-ion batteries. When X = 1 and 3, the alloys were composed of coarse supersaturated alpha-Al grains and fine alpha-Si grains spread along the boundaries, and performed high initial capacities but fast capacity fade. As X was increased to 5 and 7, the constitution of alloys was characterized by nanoscaled alpha-Al and amorphous regions, and they exhibited capacities of 924 and 764 mAh g(-1) initially, 733 and 578 mAh g(-1) at the second cycle and then maintained 391 and 351 mAh g(-1) after 50 cycles, respectively. When the Mn content was more than 10 %, an intermetallic compound Al4.01MnSi0.74 co-existed with alpha-Al and it evolved into the predominated constitution. The initial specific capacities were very high, but faded rapidly only experiencing few cycles. After lithiation, any compound with Li could not be detected in the Al85Si12Mn3 and Al83Si12Mn5 anodes, while the AlLi intermetallic compound could be detected when the Mn content was increased to 13 %. It could be considered that the appropriate phase constitution and microstructure in the Al83Si12Mn5 and Al81Si12Mn7 anodes were very beneficial to mitigating structure evolution, improving structure stability, and obtaining favorable electrochemical properties. The Al4.01MnSi0.74 compound was an active phase for Li storage in the present system, but it was responsible for serious structure evolution, poor cyclability, and pulverization.