Litcius/Paper detail

Revisiting the substitutional Mg acceptor binding energy of AlN

Ryota Ishii, Akira Yoshikawa, Mitsuru Funato, Yoichi Kawakami

2023Physical review. B./Physical review. B10 citationsDOI

Abstract

Bipolar ($n$- and $p$-type) electric conductivity control is at the heart of semiconductor technologies. However, achieving such control in ultrawide-band-gap semiconductors has been a major challenge because of the very high donor and/or acceptor binding energies of these materials. In the case of aluminum nitride (AlN), which is an ultrawide-band-gap semiconductor and one of the first candidate materials for solid-state deep-ultraviolet emitters, the substitutional magnesium (Mg) acceptor binding energy has been reported to be at least 500 meV; thus, $p$-type electric conductivity control in AlN by Mg doping is believed to be unfeasible. Here, we experimentally and theoretically revisit the substitutional Mg acceptor binding energy of AlN. Our bound exciton luminescence and impurity-related transition spectroscopic studies indicate that the substitutional Mg acceptor binding energy of AlN is well below 500 meV. This statement is supported by variational calculations using anisotropic hole effective masses derived from first-principles calculations. The three independent approaches estimate the substitutional Mg acceptor binding energy of AlN to be $330\ifmmode\pm\else\textpm\fi{}80\phantom{\rule{0.16em}{0ex}}\mathrm{meV}$. We find that considering electron-hole exchange interaction, hole anisotropy, and carrier-phonon coupling of AlN leads to a more realistic substitutional Mg acceptor binding energy.

Topics & Concepts

AcceptorBinding energyMaterials scienceBand gapExcitonCondensed matter physicsSemiconductorImpurityDopingAtomic physicsPhysicsOptoelectronicsQuantum mechanicsGaN-based semiconductor devices and materialsGa2O3 and related materialsSemiconductor materials and devices