Realistic anharmonic decay rates in the VED framework

Identify realistic values for the anharmonic decay rate τ_{anh} used in the anharmonic damping term τ^{-1}_{ANH}(q,ω) of the excitation Boltzmann equation within the Van der Waals Electrodynamics (VED) model, beyond the very-large-anharmonicity regime adopted here.

Background

To ensure finite conductivity when only long-range interactions are included, the authors introduce an anharmonic decay model for electrodynamic excitations, controlled by τ_{anh}. In the parabolic-band tests they explore the very large anharmonicity regime as a simplifying choice.

For the realistic VED treatment of BN-encapsulated graphene, they similarly focus on the very large anharmonicity regime and defer the determination of realistic τ_{anh} values to future work.

References

We can then study the very large anharmonicity regime like for the parabolic case. We leave the description of realistic value to further works.

Coupled dynamical Boltzmann transport equations with long-range electron-phonon and electron-electron interactions in 2D materials  (2604.01746 - Macheda et al., 2 Apr 2026) in Section 4 (The response functions), Subsection “Choice of τ^{-1}_{ANH},” VED case