In previous study, N3O2 pentadentate ligand H2BDPP, published on Tetrahedron(Tetrahedron: Asymmetry 2004, 15, 177.), was deprotonated and employed to react with CoCl2 to form a CoII(BDPP)(1) complex. Senior researcher Chun-Chieh Wang had found that CoII(BDPP)(1) could react with dioxygen and formed CoIIIBDPP(O2)(2) intermediate only under low temperature . CoIIIBDPP(O2)(2) was well-characterized by UV-Vis spectrum, EPR spectrum and rRaman spectrum. CoIIIBDPP(O2)(2) was found to be able to conduct HAT with substrates with weak O-H bond, like TEMPO-H, Azadol, and formed the bio-relative intermediate CoIIIBDPP(OOH). CoIIIBDPP(OOH) was crystallized under -20⁰C and well-characterized by UV-Vis spectrum, rRaman spectrum and XRD. To understand the reactivity of superoxide, especially the protonation and electron transfer process. We protonated CoIIIBDPP(O2)(2) and got a low-temp stable intermediate. The protonated superoxo, CoIII(BDPP)(O2)(H+)(C₂HF₃O₂-)(3) / CoIII(BDPP)(O2)(H+)(OTf-)(3') was well-characterized by UV-Vis spectrum, EPR spectrum and rRaman spectrum. When CoIII(BDPP)(O2)(H+)(OTf-)(3') was reacted with decamethylferrocene under -120 ⁰C , we could get a UV-Vis spectrum was similar to CoIII(BDPP)(OOH). In addition, we took two Lewis Acids, Sc(OTf)3, B(C6F5)3 , as analogues of proton. We could get almost identical UV-Vis signals and EPR signals with the protonated one after CoIIIBDPP(O2)(2) was reacted with Sc(OTf)3 and B(C6F5)3. The reaction with Sc(OTf)3 was further reduced by decamethylferrocene under -90 ⁰C. The UV-Vis spectrum shared two feature peaks with CoIII(BDPP)(OOH). The hypothetical CoIIIBDPP(OOSc)2+ was likely formed. Through this study, we believed to establish a new cobalt superoxo model to understand the protonation and electron transfer process which was still rare in bioinorganic region.