Bisphenol A (BPA) is a toxic substance that is released into the environment mainly from paint, polymer, plastics and pharmaceutical industries. In this study, spinel Co$_3$O$_4$ consisting of Co$^{2+}$/(Co$^{3+}$)$_2$O$_4$ nanospheres with excellent specific surface properties were systematically synthesized via a simple hydrothermal approach preceded by calcination. The as-synthesized Co$_3$O$_4$ spinels were used for peroxymonosulfate (PMS) activation to reduce the bisphenol A (BPA). The effects of operating parameters including PMS dosage, initial pH, catalyst dosage, and co-existing ions were detected during the BPA degradation. It was observed that at neutral pH, the nano-Co$_3$O$_4$/PMS system effectively degrades the BPA (∼92%) with very low cobalt leaching and excellent recyclability. Control experiment analysis confirms the magnificent performance of the Co$_3$O$_4$/PMS system and the synergistic interaction between Co$_3$O$_4$ and PMS. Various characterization techniques were used to determine the thermal, textural and structural properties. A chemical quenching study confirmed that both hydroxyl radicals ($^•$OH) and sulfate radicals (SO$_4^{•−}$) promotes BPA oxidation. The chloride (Cl$^-$) ions and dihydrogen phosphate ions (H$_2$PO$_4^-$) have little inhibition effect while adding humic acid (HA) and HCO$_3^-$ inhibits the BPA oxidation. Separation techniques such as high-performance liquid chromatography (HPLC) coupled with mass spectroscopy (MS) were used to identify the oxidative by-products and the mineralization pathway of BPA reduction. First-order pseudo-kinetics were observed for BPA degradation. However, the power law model also fits n$^{th}$-order kinetics models.