Abstract

Ion migration and electron transmission are vital for manganese dioxides in zinc ion batteries. δ-MnO2 is believed to be more suitable for zinc ion storage due to its layered structure. However, the performance of δ-MnO2 is still hampered by the frustrating conductivity and sluggish reaction kinetics. Herein, atomic engineering is adopted to modify δ-MnO2 at the atomic level to obtain oxygen-deficient δ-MnO2 (N-MnO2). Meanwhile, hollow carbon microtubes (HCMTs) obtained from green and renewable energy grass are proposed as cross-connected electron transmission matrices (CETMs) for MnO2. The biomass-derived CETMs not only optimize reaction kinetics but also facilitate the ion storage performance of MnO2. The as-prepared N-MnO2@HCMTs exhibit high rate capability and enhanced pseudocapacitve behavior contributed by the oxygen-deficient N-MnO2 and CETMs. Ex situ analysis reveals the reversible insertion/extraction of H+ and Zn2+ in N-MnO2@HCMTs during charge/discharge processes. Moreover, the quasi-solid-state N-MnO2@HCMTs//Zn cells are assembled and they deliver extraordinary discharge capacity and a long cyclic lifespan. This study may provide insights for further exploration of cathode materials in AZIBs and promote the large-scale production of aqueous Zn-MnO2 batteries.

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