摘要
High energy ball milling (HEBM) method was applied to synthesize Ni (OH)2 with different doped elements sub-stitution for Ni^2+. The morphology, structure and electrochemical behavior of prepared powders were studied. The re-suits reveal that all the synthesized Ni(OH)2 particles were in sub-micron sizes and greatly agglomerated. Co-, Mg-,Fe- or Mn-doped Ni (OH) 2 was of β-phase with 0.400-0.500 nm crystal interlayer distance, while A1- and Zn-doped products displayed a-phase with larger crystal interlayer spaces. The electrochemical mechanisms of synthe-sized Ni(OH)2 electrodes were discussed by EIS spectra. The specific capacity of Co-doped Ni (OH)2 is 245 mA·h · g^-1, i. e. , 60 mA· h · g^-1 higher than that of Al-doped electrode, which has the highest discharging plat-form of a mid-voltage of 1.30 V.
High energy ball milling (HEBM) method was applied to synthesize Ni (OH)2 with different doped elements sub-stitution for Ni^2+. The morphology, structure and electrochemical behavior of prepared powders were studied. The re-suits reveal that all the synthesized Ni(OH)2 particles were in sub-micron sizes and greatly agglomerated. Co-, Mg-,Fe- or Mn-doped Ni (OH) 2 was of β-phase with 0.400-0.500 nm crystal interlayer distance, while A1- and Zn-doped products displayed a-phase with larger crystal interlayer spaces. The electrochemical mechanisms of synthe-sized Ni(OH)2 electrodes were discussed by EIS spectra. The specific capacity of Co-doped Ni (OH)2 is 245 mA·h · g^-1, i. e. , 60 mA· h · g^-1 higher than that of Al-doped electrode, which has the highest discharging plat-form of a mid-voltage of 1.30 V.
基金
Supported by the National Natural Science Foundation of China(No.20273047).
