Herein, we have reviewed the recent developments of rechargeable manganese dioxide−zinc (MnO₂−Zn) batteries under both alkaline and mild acidic electrolyte systems. The evolution pathway of MnO₂−Zn system from Leclanché cell to alkaline primary batteries and from primary to secondary batteries is chronologically depicted. Several adverse phenomena are associated with the reversibility of metallic zinc negative electrode under alkaline (pH 14) electrolyte mediums, and these may include zinc dendrite formation, passivation of electrode surface, shape change of the electrode, zincate crossover through separator and hydrogen evolution upon charging. The MnO₂ positive electrode also experiences few performance degrading issues under alkaline mediums; like generation of electrochemically inert phases (Mn₃O₄ and ZnMn₂O₄) in the electrode upon deep‐discharge and Mn‐dissolution in the electrolyte. The mitigation measures of these challenges are well documented and systematically analysed. On the invention of zinc‐ion batteries, the MnO₂−Zn secondary batteries are assembled under mild acidic (pH 4–6) electrolytes, and eventually, several adverse effects of alkaline systems are drastically nullified. However, recent scientific and technical efforts are coined to address the challenges of large‐scale MnO₂−Zn batteries in mild acidic mediums, and formulate the optimization strategies. This review culminates with a few smart designs of MnO₂−Zn batteries, whereas, truly path‐breaking concepts are associated with. To the best of our knowledge, it is the first review that covers the entire spectrum of MnO₂−Zn system in both alkaline and mild acidic mediums, along with evolution pathways.