The semi-solid slurry of a hypoeutectic Al-Si alloy was manufactured by low superheat pouring and weak elec- tromagnetic stirring. The effects of pouring temperature and stirring power on the semi-solid slurry were investigated. The results indicated that the semi-solid slurry to satisfy rheocasting can be manufactured by low superheat pouring and weak electromagnetic stirring. The pouring temperature (or superheat) and the stirring power remarkably affected the morphology of primary α-Al and the size of primary α-Al, and there is no obvious effect of stirring time on primary α-Al. Compared with the samples made by low superheat pouring with no stirring, the nucleation rate, particle morphology and grain size of primary α-Al in A356 were markedly improved by low superheat pouring and weak electromagnetic stirring. On the condi- tion of weak electromagnetic stirring, the pouring temperature with low superheat can be suitably raised to reach the effec- tiveness obtained from the lower pouring temperature without stirring. The semi-solid slurry of a hypoeutectic Al-Si alloy was manufactured by low superheat pouring and weak elec- tromagnetic stirring. The effects of pouring temperature and stirring power on the semi-solid slurry were investigated. The results indicated that the semi-solid Slurry to satisfy rheocasting can be manufactured by low superheat pouring and weak electromagnetic stirring. The pouring temperature (or superheat) and the stirring power remarkably affected the morphology of primary α-Al and the size of primary α-Al, and there is no obvious effect of stirring time on primary α-Al. Compared with the samples made by low superheat pouring with no stirring, the nucleation rate, particle morphology and grain size of primary α-Al in A356 were markedly improved by low superheat pouring and weak electromagnetic stirring . On the condi- tion of weak electromagnetic stirring, the pouring temperature with low superheat can be lipped raised to reach the effectified obtained from the lowe r pouring temperature without stirring.