Lithium insertion in layered materials as battery cathodes

“…Copyright 1986 Kluwer Academic Press coordination that changes the octahedral one (TP ! Oh transition) [26][27][28]. The structure modification is accompanied by an increase of the M-X band ionicity in agreement with the respective stability of the new atomic arrangement, the Coulomb repulsion between partially charged ligands favoring the octahedral form.…”

“…4.12) [31]. This superlattice formation was also observed in the incremental capacity dQ/dV obtained from electrochemical measurements [28] and in the Raman scattering spectra of Li 0.3 MoS 2 [32,33]. However, we do expect that the lithiation process is accompanied by the raising of the Fermi level due to the charge transfer from Li intercalation.…”

Reliability of the Rigid-Band Model in Lithium Intercalation Compounds

“…Copyright 1986 Kluwer Academic Press coordination that changes the octahedral one (TP ! Oh transition) [26][27][28]. The structure modification is accompanied by an increase of the M-X band ionicity in agreement with the respective stability of the new atomic arrangement, the Coulomb repulsion between partially charged ligands favoring the octahedral form.…”

“…4.12) [31]. This superlattice formation was also observed in the incremental capacity dQ/dV obtained from electrochemical measurements [28] and in the Raman scattering spectra of Li 0.3 MoS 2 [32,33]. However, we do expect that the lithiation process is accompanied by the raising of the Fermi level due to the charge transfer from Li intercalation.…”

Reliability of the Rigid-Band Model in Lithium Intercalation Compounds

“…[ 5,6 ] Intercalation chemistry in layered compounds, where the van der Waals (vdW) gap of the host compound is filled with guest (intercalant) atoms [ 7 ] or molecules, [ 8 ] is a cornerstone in many processes and forms the basis of modern energy storage devices. [ 9,10 ] In some cases, the intercalation process is designed to modify the properties of the host material, [ 11 ] whereas in other cases, intercalation produces a continuous 2D material of interest, that would be hard to realize without the template of the confining environment of the vdW gap. For example, 2D gallium and indium that are grown by atomic intercalation at the interface of SiC and graphene, show potential for superconducting devices, topological phenomena, and advanced optoelectronic properties.…”

Enhancing Light–Matter Interactions in MoS₂ by Copper Intercalation

“…Furthermore, the weak van der Waals force between MoS 2 layers allows Li + ions to diffuse without a significant increase in volume expansion. These properties make MoS 2 an ideal electrode material for advanced LIBs [54, 55]. …”

Synthesis of MoS₂and MoO₂for their applications in H₂generation and lithium ion batteries: a review