Reply to comment by Witte et al. on "Isochoric, isobaric, and ultrafast conductivities of aluminum, lithium,and carbon in the warm dense matter regime", Phys. Rev. E 96, 053206 (2017)

Abstract

In Phys. Rev. E, 99, 047201 (2019) Witte et al. have commented on our conductivity calculations [Phys. Rev. E 96, 053206 (2017)] for warm dense matter (WDM). (i) They criticize our use of the spherically-averaged structure factor S(k) for calculations of the static conductivity σ of FCC aluminum - a common approximation for polycrystalline materials. They themselves give no calculations as their method using density-functional theory (DFT) and molecular dynamics (MD) based Kubo-Greenwood (KG) calculations becomes impractical for cold ions. (ii) We are satisfied that Witte et al. no longer claim a factor of 1.5 change in σ on changing the exchange-correlation (XC) functional used. (iii) They have provided computer-intensive calculations of σ for aluminum using DFT-MD-KG simulations, for temperatures T up to 15 eV but using only N=64 atoms in the simulation, where as a mixture of ionic species needs a far larger N to be credible. We present multi-species conductivity calculations via a parameter-free DFT theory [Phys. Rev. E. 52, 5352 (1995)] for 5 eV to 50 eV. (iv) The conductivities obtained from well-converged DFT-MD-KG methods show a significant underestimate of σ; this is especially evident for the isochoric conductivity σ ic extrapolating to 3.5× 106 S/m, i.e, even below the experimental isobaric value of 4.1× 106 S/m at the melting point, when a value of 5× 106 S/m is anticipated.