Accessing Structural, Electronic, Transport and Mesoscale Properties of Li-GICs via a Complete DFTB Model with Machine-Learned Repulsion Potential

Abstract: Lithium-graphite intercalation compounds (Li-GICs) are the most popular anode material for modern lithium-ion batteries and have been subject to numerous studies—both experimental and theoretical. However, the system is still far from being consistently understood in detail across the full range of state of charge (SOC). The performance of approaches based on density functional theory (DFT) varies greatly depending on the choice of functional, and their computational cost is far too high for the large supercel… Show more

“…This is due to the simple one-parameter form of the repulsive potential. Nonetheless, it would be straightforward to refine PTBP with a more flexible and/or many-body repulsive potential. ,,, …”

“…Nonetheless, it would be straightforward to refine PTBP with a more flexible and/or many-body repulsive potential. 42,59,60,61 As one of the most challenging elements for DFTB, phosphorus is considered in the bottom row of Figure 7c (see Figure S7 for additional comparisons). Here, four different prototypes display significant weights in the loss function, namely, graphite, BCC, diamond, and β-Sn (with Boltzmann factors of 0.11, 0.13, 0.22, and 0.40, respectively).…”

Obtaining Robust Density Functional Tight-Binding Parameters for Solids across the Periodic Table

“…This is due to the simple one-parameter form of the repulsive potential. Nonetheless, it would be straightforward to refine PTBP with a more flexible and/or many-body repulsive potential. ,,, …”

“…Nonetheless, it would be straightforward to refine PTBP with a more flexible and/or many-body repulsive potential. 42,59,60,61 As one of the most challenging elements for DFTB, phosphorus is considered in the bottom row of Figure 7c (see Figure S7 for additional comparisons). Here, four different prototypes display significant weights in the loss function, namely, graphite, BCC, diamond, and β-Sn (with Boltzmann factors of 0.11, 0.13, 0.22, and 0.40, respectively).…”

Obtaining Robust Density Functional Tight-Binding Parameters for Solids across the Periodic Table

“…Another source of potential error is non-local DFT's known issue with modelling highly polarizable ions such as Li 102 due to the use of atomic rather than ionic volumes. 103 Anniés et al 104 identify this issue for Pande and Viswanathan's 97 DFT-based Ising model which performs well for low Li abundance stages but not for high Li abundance stages. Further advancements can be made by considering graphite nanoparticles in electrolyte environments at applied voltage as in experimental electrochemistry.…”

Ab initio study of lithium intercalation into a graphite nanoparticle

Material design modelling for optimisation of lithium battery fast charging