Critical electronic structures controlling phase transitions induced by lithium ion intercalation in molybdenum disulphide

Xiaobo Chen,Jun Li,Zhenlian Chen

doi:10.1007/s11434-013-5834-y

Xiaobo Chen, Jun Li + Show 1 more

Open Access

https://doi.org/10.1007/s11434-013-5834-y

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Abstract

We report on first-principles studies of lithium-intercalation-induced structural phase transitions in molybdenum disulphide (MoS2), a promising material for energy storage in lithium ion batteries. It is demonstrated that the inversion-symmetry-related Mo-S p-d covalence interaction and the anisotropy of d-band hybridization are the critical factors influencing the structural phase transitions upon Li ion intercalation. Li ion intercalation in 2H-MoS2 leads to two competing effects, i.e. the 2H-to-1T transition due to the weakening of Mo-S p-d interaction and the D 6h crystal field, and the charge-density-wave transition due to the Peierls instability in Li-intercalated 2H phase. The stabilization of charge density wave in Li-intercalated MoS2 originates from the enhanced electron correlation due to nearest-neighbor Mo-Mo d-d covalence interaction, conforming to the extended Hubbard model. The magnitude of charge density wave is affected by Mo-S p-d covalence interaction and the anisotropy of d-band hybridization. In 1T phase of Li-intercalated MoS2, the strong anisotropy of d-band hybridization contributes to the strong Fermi surface nesting while the d-band nonbonding with S-p facilities effective electron injection.

Highlights

Molybdenum disulphide (MoS2) is increasingly important for a variety of applications in electronics [1,2,3], optics [4,5,6], hydrogen storage [7], catalysts [8,9], lubricants [10,11], and double-layer capacitors [12]
We report on first-principles studies of lithium-intercalation-induced structural phase transitions in molybdenum disulphide (MoS2), a promising material for energy storage in lithium ion batteries
The valence band maximum (VBM) is shifted from Γ to A and the conduction band minimum (CBM) is shifted from the midway of Γ-K to H due to the band folding effect induced by the increase of stacking periodicity of S-Mo-S slabs along the c axis

Summary

Structures and computational details

MoS2 crystal consists of S-Mo-S tri-layer slabs held together by weak vdW force. Changes in the ion arrangement within an S-Mo-S slab may lead to two typical building blocks, i.e. trigonal prism and octahedron. For the D6h point group of 2H phase, they are at interstitial octahedral sites within vdW gaps, even though the trigonal prismatic MoS6 unit has no inversion center. These are potential sites for Li. ion intercalation. For pure MoS2, the vdW correction in Grimme’s DFT-D2 scheme [50] is used for structural determination. In our PBE optimization, the original hexagonal lattice distorts slightly into a triclinic one, resulting in a total energy reduction of ~50 meV/f.u

Electronic properties: p-d interaction and d-band hybridization

Phase stability of MoS2 polytypes

Phase stability upon Li intercalation

Formation and stabilization of CDW after Li intercalation

Conclusion