In this study, the effects of Er content on the microstructures and mechanical properties of Er-doped CoCrNi medium entropy alloys (MEAs) and CoCrNi medium entropy alloy films (MEAFs) were systematically investigated. In the bulk alloy part, a series of Er-doped CoCrNi MEAs with 0, 0.1, 0.3, 0.5, 0.7 ,1.0, and 1.3 at.% Er was fabricated by vacuum arc melting. It was found that Er element addition led to the formation of Er-Ni riched hexagonal phase (CaCu5 type) precipitates embedded in the original FCC matrix. The volume fraction of the HCP phase increased with the increase in the Er content. The grain sizes decreased from 18.1 to 5.1 µm as the Er content increased from 0 to 1.3 at.%. Both the ultimate tensile strength (UTS) and Vickers hardness increased with the increasing Er content, while the ductility decreased. Compared to the CoCrNi MEA, the UTS and Vickers hardness of (CoCrNi)98.7Er1.3 MEA increased from 878 MPa to 1143 MPa and 212 HV to 263 HV, respectively. In addition, the nanoindentation measurements on different phases indicated that the HCP phase had a high hardness ( ~ 7.87 GPa), which was almost two times of the FCC phase ( ~ 4.72 GPa). The strengthening mechanisms of the present alloys included solid-solution strengthening, grain boundary strengthening, and precipitation strengthening. In the thin film part, a series of (CoCrNi)100-xErx (x = 0, 0.89, 1.93, 2.57, 3.35, and 4.08) MEAFs was fabricated by radio frequency magnetron (RF) co-sputtering. A crystal structure transition from single FCC phase to amorphous structure could be observed from XRD and TEM results with the increasing Er amounts from 0 to 4.08 at.%. According to TEM results, the SAED pattern of Er1.93 revealed a crystal-amorphous dual-phase structure. Nanoindentation tests indicated an initial increase in hardness and Young’s modulus, reached a maxima value at x = 1.93, and then decreased with further Er addition. Similar trends were also shown in the yield strength and compressive strength. The initial increment of mechanical properties could be ascribed to the solid solution strengthening and grain refinement strengthening with small Er additions. However, the excess Er addition would be accompanied by the inverse Hall–Petch effect, leading to the softening.