Optimal coloring and strain-enhanced superconductivity in LinBn+1Cn-1

Abstract

Boron-rich lithium borocarbides are promising candidates for phonon-mediated high-temperature superconductors due to their metallic σ-bonding electrons. Here, we use the cluster expansion method to identify energetically stable configurations (colorings) of Li2B3C and Li3B4C2, which are characterized by a distinctive pattern of alternating B-B and B-C zigzag chains. Surprisingly, the optimal configuration of Li2B3C exhibits an extremely low superconducting transition temperature of Tc < 0.03 K, which is attributed to the suppression of deformation potentials near the Fermi level caused by the specific electron filling of B-B zigzag chains. However, the σ-bonding electrons at the Fermi level are highly sensitive to external strain or pressure. Specifically, applying a -5\% compressive uniaxial strain can significantly enhance the electron-phonon coupling and the Eliashberg spectral function, boosting up Tc to 37 K. This work not only presents a novel strategy for achieving phonon-mediated high-temperature superconductivity in LinBn+1Cn-1 compounds but also provides valuable insights into the complex interplay between electronic structure and superconducting interaction.

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