High rate capability of a BaTiO3-decorated LiCoO2 cathode prepared via metal organic decomposition

Takashi Teranishi, Naoto Katsuji, Yumi Yoshikawa, Mika Yoneda, Hidetaka Hayashi, Akira Kishimoto, Koji Yoda, Hidefumi Motobayashi, Yuzo Tasaki

Research output: Contribution to journalArticlepeer-review

8 Citations (Scopus)


Metal organic decomposition (MOD) using octylic acid salts was applied to synthesize a BaTiO3-LiCoO2 (BT-LC) composite powder. The Ba and Ti octylates were utilized as metal precursors, in an attempt to synthesize homogeneous BT nanoparticles on the LC matrix. The BT-LC composite, having a phase-separated composite structure without any impurity phase, was successfully obtained by optimizing the MOD procedure. The composite prepared using octylate precursors exhibited a sharper distribution and better dispersibility of decorated BT particles. Additionally, the average particle size of the decorated BTs using metal octylate was reduced to 23.3 nm, compared to 44.4nm from conventional processes using Ba acetate as well as Ti alkoxide as precursors. The composite cathode displayed better cell performance than its conventional counterpart; the discharge capacity of the metal octylate-derived specimen was 55.6mAh/g at a 50C rate, corresponding to 173% of the capacity of the conventional specimen (32.2mAh/g). The notable improvement in high rate capability obtained in this study, compared with the conventional route, was attributed to the higher density of the triple junction formed by the BT-LC-electrolyte interface.

Original languageEnglish
Article number10TB01
JournalJapanese Journal of Applied Physics
Issue number10
Publication statusPublished - Oct 2016

ASJC Scopus subject areas

  • Engineering(all)
  • Physics and Astronomy(all)


Dive into the research topics of 'High rate capability of a BaTiO3-decorated LiCoO2 cathode prepared via metal organic decomposition'. Together they form a unique fingerprint.

Cite this