Dynamically tunable polarized mid-infrared light-emitting diodes from polarization singularities in a band-edge Weyl node.
Junrong Zhang, Fengyuan Xuan, Jiexi Song, Junsheng Xu, Dong Wang, Quanlong Zhang, Qinghua Han, Keyu Cheng, Yaning Liang, Xingang Hou, Xiangyi Wang, Jing Xu, Yuan Gan, Xicheng Yang, Bingyan Ren
Abstract
Open AccessThe polarization states of light-emitting devices in conventional semiconductors are typically deterministically fixed by optical transition selection rules. However, in emerging Weyl semiconductors, band-crossing Weyl nodes introduce exotic polarization contrasts, making emission polarization sensitive to carrier dynamics. Here, we demonstrate mid-infrared light-emitting diodes based on van der Waals tellurium, a Weyl semiconductor featuring a Weyl node precisely at the conduction band minimum (CBM). These devices demonstrate high polarization tunability, with linear polarization degrees continuously adjustable from ~100% (low carrier density) to 36% (high carrier density). First-principles calculations reveal that this tunability originates from polarization singularities induced by CBM-located Weyl nodes, where the polarization state is dynamically modulated by the quasi-Fermi level shift and hot-carrier recombination under varying injection densities. Our findings establish band-edge Weyl nodes as a promising platform for tunable polarized emitters and open alternative avenues for topological optoelectronics.