论文信息 - Electrochemical intercalation and deintercalation of NaxMnO2 bronzes

Electrochemical intercalation and deintercalation of NaxMnO2 bronzes

Abstract Various NaxMnO2 bronzes have been electrochemically deintercalated. Na0.40MnO2 has a channel structure which is maintained for a large intercalation range (0.30 ≤ × ≤ 0.58). In order to explain the upper intercalation limit, an ordered sodium distribution between two types of Na+ sites is proposed. Na0.70MnO2 and α-NaMnO2 have lamellar structures of P2 and 0′3 types. During intercalation the original P2 type is maintained for 0.45 ≤ × ≤ 0.85 while two reversible structural transitions are observed from α-NaMnO2. A similar behavior occurs during the deintercalation of the high-temperature β-NaMnO2 variety. In each case of the structural transition the double octahedral layers remain unchanged. Electronic localization (increased by Mn3+ Jahn—Teller effect) tends to trap the Na+ ions and therefore increases the relaxation time of the investigated materials.

[1] A. D. Wadsley. The crystal structure of psilomelane, (Ba, H2O)2Mn5O10 , 1953 .

[2] P. Hagenmuller,et al. Electrochemical intercalation of sodium in NaxCoO2 bronzes , 1981 .

[3] B. Raveau,et al. Nouveaux oxydes à structure en feuillets: Les titanates de potassium non-stoechiométriques Kx(MyTi2−y)O4 , 1980 .

[4] C. Delmas,et al. Les phases KxMnO2 (x < 1) , 1976 .

[5] P. Hagenmuller,et al. Trigonal Prismatic or Octahedral Surrounding in Sheet Oxides ? , 1981 .

[6] P. Hagenmuller,et al. Etude par desintercalation electrochimique des systemes NaxCrO2 et NaxNiO2 , 1982 .

[7] P. Hagenmuller,et al. Sur quelques nouvelles phases de formule NaxMnO2 (x ⩽ 1) , 1971 .

[8] P. Hagenmuller,et al. A study of the NaxTiO2 system by electrochemical deintercalation , 1983 .