Factors affecting the electron-phonon coupling in FeSe under pressure

Hydrostatic pressure on superconductor FeSe increases the Wyckoff position, z(Se), and decreases lattice constants. However, previously only the increasing of z(Se) was emphasized to be important in determining the electron-phonon coupling. We explicitly study each of the two factors individually to understand its influence on the electron-phonon coupling, band structure and Raman frequencies. We find that the increasing of z(Se) enhances the states around the Fermi level more, while the decreasing of the lattice constants enhances the phonon frequencies more, which together increase the electron-phonon coupling under pressure. Based on the above facts, we predict and prove that the in-plane biaxial strain on FeSe increases the electron-phonon coupling due to the increasing z(Se) value and the decreasing in-plane lattice constant. Our results uncover the factors affecting the increase of the electron-phonon coupling and provide information on how to enhance the electron-phonon coupling in FeSe.

Automated summary

Increasing z(Se) enhances states around the Fermi level, while decreasing lattice constants enhances phonon frequencies, both of which increase the electron-phonon coupling. In FeSe, in-plane biaxial strain increases the electron-phonon coupling by increasing z(Se) value and decreasing in-plane lattice constant.