Cs<sub>2</sub>Cd<sub>1–<i>x</i></sub>Mn<sub><i>x</i></sub>Cl<sub>4</sub> Nanoplatelets for Thermal Quenching Resistance and Luminescence Tuning
Biling Zheng, Bao Ke, Chengzhi Yang, G. P. Zhang, Xiaodong Shen, Weizheng Liang, Xian-Ci Zhong, Bingsuo Zou
Abstract
Two-dimensional (2D) metal halides exhibit unique optical properties, attracting significant attention. Cs 2 CdCl 4 with a 2D layered Ruddlesden–Popper (R–P) phase demonstrates poor optical characteristics, limiting its potential application. The introduction of Mn 2+ doping improved its luminescence. The weak-blue emission of pure Cs 2 CdCl 4 shifts to an orange-red color after Mn doping, which is caused by Mn 2+ and Mn–Mn ferromagnetic coupling in the point–point connection between neighbored octahedra by increasing the feed ratio of Mn 2+ . Under strong quantum confinement effects, the introduction of Mn 2+ into the 2D Cd–Cl lattice leads to the formation of exciton magnetic polarons (EMPs) and localized exciton magnetic polarons (LEMPs), significantly influencing their optical properties and resulting in a gradual red shift in their emission bands. The photoluminescence quantum yield (PLQY) is tremendously increased to 46% in the doped samples, accompanied by tunable emissions achieved through an increasing amount of Mn doping. This enhancement and shift in luminescence are attributed to an energy transfer pathway from the defect state luminescence of Cs 2 CdCl 4 to the dominant luminescence via single Mn 2+ and Mn–Mn pair d–d transitions. This study indicates the spin–spin coupling effect of doped metal ions on the luminescence enhancement and shift in 2D layered halides, thereby presenting new prospects for practical applications of R–P phase 2D layered nanoplatelets.