Electronic structure of the electrode/electrolyte interface: large-scale tight-binding quantum chemical simulation

• Published in: Solid state ionics Vol. 175; no. 1; pp. 847 - 850
• Main Authors: Makino, Yusuke, Kusagaya, Tomonori, Suzuki, Ken, Endou, Akira, Kubo, Momoji, Selvam, Parasuraman, Ota, Hirokuni, Yonekawa, Fumihiro, Yamazaki, Nobuyuki, Miyamoto, Akira
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.11.2004
• Subjects: Electrode/electrolyte interface; Ethylene carbonate; LiCoO 2; LiPF 6; Lithium secondary battery; Tight-binding quantum chemical molecular dynamics; Lithium secondary battery; LiCoO 2; LiPF 6; 07.05.Tp; Tight-binding quantum chemical molecular dynamics; 28.52.Av; 84.60.Dn; Ethylene carbonate; 85.80.Dg; Electrode/electrolyte interface
• ISSN: 0167-2738; 1872-7689
• DOI: 10.1016/j.ssi.2004.09.053

Recently, we have succeeded in the development of new tight-binding quantum chemical molecular dynamics code “Colors”, based on our original tight-binding theory. It realizes 5000 times acceleration compared to the conventional first-principles molecular dynamics method and enables us to simulate huge simulation models. Hence, in the present study we applied our new tight-binding quantum chemical molecular dynamics method to the investigation of the electronic structure of the interface of the Li 0.5CoO 2 electrode and the ethylene carbonate (EC) electrolyte along with LiPF 6. Our electronic structure calculations for the Li 0.5CoO 2/EC+LiPF 6 interface suggest that the EC+LiPF 6 electrolyte significantly stabilizes the instability of the Li 0.5CoO 2 surface. Moreover, the detailed analyses for the electronic structure of the electrode/electrolyte interface were also performed. These analyses cannot be realized by the conventional first-principles approach, since it requests huge computational time for such large and complicated system. Hence, we confirmed the effectiveness of our tight-binding quantum chemical molecular dynamics approach to the investigation of the electrode/electrolyte interface on electronic- and atomic-level.