In this research, the effect of equal channel angular extrusion (ECAE) on the impression creep behavior of magnesium alloy (Mg-5wt.%Sn-1wt.%Ca) was investigated. Energy dispersive system (EDS) was used for chemical composition analysis. The precipitation phases confirmed by X-ray diffraction pattern (XRD) were Mg2Sn and CaMgSn. The microstructures were examined by optical microscopy (OM). Instron 8501 was used for impression creep test. The stress exponent decreases from n=7.7 for the as-cast sample to n=5.68 for the sample after four passes of ECAE process (N=4). It suggests that the dominant creep mechanism of alloy changes from power-law breakdown region to grain boundary sliding region. The creep activation decreases from 148.2KJ/mol for the as-cast sample to 95.8KJ/mol for N=4 sample. It suggests that the dominant diffusion mechanism of alloy changes from dislocation slip to grain boundary diffusion. When the applied stress is 350MPa at 200℃, N=1 sample has the best creep resistance. Its creep rate is 5.4E-4. Under the same test condition , the N=4 sample has the worst creep resistance. Its creep rate is 1.24E-3. It's because of the change of dominant creep mechanism. The N=4 sample has the smallest gains, which means the most grain boundaries, so its creep resistance is worse than the others.