Abstract
Nanocrystalline cesium lead halide perovskites (CsPbX3, X = Cl, Br, and I) form an exciting new class of semiconductor materials showing quantum confinement. The emission color can be tuned over the full visible spectral region making them promising for light‒emitting applications. Further control over the optical and magnetic properties of quantum dots (QDs) can be achieved through doping of transition metal (TM) ions such as Mn2+ or Co2+. Here we demonstrate how, following QD synthesis in the presence of a Mn‒precursor, dropwise addition of silicon tetrachloride (SiCl4) to the QDs in toluene results in the formation of Mn‒doped CsPbCl3 QDs showing bright orange Mn2+ emission around 600 nm. Evidence for successful doping is provided by excitation spectra of the Mn2+ emission, with all features of the CsPbCl3 QD absorption spectrum and a decrease of the 410 nm excitonic emission life time with increasing Mn‒concentration, giving evidence for enhanced exciton to Mn2+ energy transfer. As a doping mechanism we propose a combination of surface etching and reconstruction and diffusion doping. The presently reported approach provides a promising avenue for doping TM ions into perovskites QDs enabling a wider control over optical and magnetic properties for this new class of QDs.
Highlights
Nanocrystalline cesium lead halide perovskites (CsPbX3, X = Cl, Br, and I) form an exciting new class of semiconductor materials showing quantum confinement
Colloidal CsPbBr3 quantum dots (QDs) have been reported with efficient narrow band emission (FWHM = 86 meV; quantum yield = 90%) and reduced emission blinking making them promising for the lighting and display industry[15]
CsPbCl3 QDs were prepared using a similar procedure as reported by Kovalenko et al.[13]
Summary
No incorporation of Mn2+ was observed after thorough washing of the CPC‒Mn QDs with acetone before the addition of SiCl4 (Fig. S7) This shows that the (apolar) Mn‒precursor is absorbed at the CPC QD surface after the initial QD synthesis procedure in the presence of the Mn‒stearate precursor. The presently reported synthesis approach is promising for exploring other transition‒metal or lanthanide ion doped perovskite QDs in order to gain a wider control over the optical and magnetic properties of doped QDs for applications in the fields of lighting and spintronics
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