The chemical composition of reduced magnetic particles strongly correlates with the reduction potential of their metal species. However, this phenomenon rarely has been investigated in magnetic-dielectric absorbers. In this manuscript, a formaldehyde-assisted metal-ligand crosslinking strategy is employed to incorporate different metal species (Fe³⁺, Co²⁺, Co²⁺-Ni²⁺) into the colloidal frameworks by the chelating coordination. Because of their different reduction potentials, porous magnetic carbon spheres (PMCSs) with adjustable magnetic-composition and micro-mesoporous characteristics are constructed via the subsequent annealing process. Compared with self-assembly polyphenol derived porous carbon spheres (PCSs), these PMCSs, including Fe₃O₄-PMCSs, Co-PMCSs and CoNi-PMCSs, exhibit promoted impedance matching and superior microwave absorption attenuation owing to the additional magnetic resonance and synergistic effect. As results, the optimal reflection loss and corresponding bandwidth are −48.6 dB and 7.8 GHz, −45 dB and 8.6 GHz, −53.2 dB and 5.1 GHz for Fe₃O₄-PMCSs, Co-PMCSs and CoNi-PMCSs with only 15 wt% filler loading, both are higher than PCSs (−39.3 dB and 4.8 GHz). This study inspires us a novel inspiration in constructing of adjustable magnetic-composition and the fabricated PMCSs can be used as lightweight microwave absorbers in the application of electromagnetic protection.