MnO attracts increasing attention as a lithium-ion battery anode material due to large theoretical capacity and relatively low cost, but its highly instable structure and low conductivity severely plague cycling stability. In addition to improved performance, easy preparation is also important for the development of MnO anode, and hence both of these aspects need attention. Toward this end, herein, a high-performance MnO-based anode material, composed of carbon coated porous nanoclusters assembled from smaller secondary Fe-doped MnO nanoparticles (denoted as Fe-MnO@C), has been prepared through a facile route. The findings demonstrate that the combination of Fe doping and carbon coating enables Fe-MnO@C to have higher structural stability and faster electrochemical kinetics than MnO and MnO@C counterparts. As a result, Fe-MnO@C anode shows outstanding lithium storage performances, maintaining 1038.4 and 512.3 mAh g−1 at 200 and 1000 mA g−1 after 320 and 400 cycles, respectively. Finally, this work not only offers a feasible method for improving MnO anode performance, but also gives a constructive reference for designing facile methods to prepare other advanced metal oxide-based anode materials.