Zn-Enhanced Perovskite Nanocrystals: Superior Spin-Coated Display Layers

Hybrid perovskite nanocrystals like MAPbBr₃ have revolutionized display color-conversion layers with narrow emission and high efficiency, but lead toxicity and thermal drift limit their practicality. By partially substituting Pb²⁺ with eco-friendly Zn²⁺ and co-introducing Cl⁻, researchers have engineered MAPb₁₋ₓZnₓBr₃₋₂ₓCl₂ₓ nanocrystals that maintain phase purity up to 150 °C. Spin-coated into uniform PMMA composites, these lead-reduced emitters achieve record-high performance for next-gen displays.

Why Zn-Doped, Lead-Reduced NCs Matter

• Toxicity Reduction: Zn²⁺ replaces a portion of Pb²⁺, making the material safer for scale-up.
• Phase & Thermal Stability: Co-doping with Cl⁻ locks the cubic phase, preventing degradation at elevated temperatures.
• Tunable Emission: Zn content adjusts bandgap for precise color targeting.

Ligand-Assisted Reprecipitation & Spin Coating Workflow

1. Precursor Preparation: Dissolve MABr, PbBr₂, and ZnCl₂ in DMF/DMSO.
2. Nanocrystal Formation: Inject into toluene/ethyl acetate under vigorous stirring (LARP method).
3. Purification: Centrifuge and re-disperse NCs in nonpolar solvent.
4. Film Deposition:
   • Disperse NCs in PMMA solution
   • Spin-coat onto glass or flexible substrates for a smooth composite layer
   • Soft-bake/anneal to remove residual solvent and lock in the cubic phase

Record-High Photoluminescence & Color Coverage

• Quantum Yield: 95 % at x = 0.1, with a narrow 21 nm FWHM emission peak
• Phase Purity: XRD confirms no secondary phases up to 20 mol % ZnCl₂
• Display-Grade Green: Emission at (0.15, 0.79) CIE—covering 97 % of the Rec.2020 gamut

Thermal Robustness & Phonon-Exciton Dynamics

Temperature-dependent PL studies reveal stronger phonon–exciton coupling with Zn inclusion, enhancing radiative efficiency. Crucially, no chromatic shift occurs up to 150 °C thanks to the tighter lattice afforded by Zn’s smaller ionic radius.

Why Navson Spin Coaters Are Key

• Uniform Thickness: Precise speed control delivers reproducible NC/PMMA films.
• Flexible Recipes: Easily swap solvents, dopant levels, and substrate sizes.
• High Throughput: Rapid spin and bake cycles support large-area coating for pilot-scale runs.

Conclusion & Next Steps
Zn-doped MAPb₁₋ₓZnₓBr₃₋₂ₓCl₂ₓ nanocrystals spin-coated into PMMA open the door to safer, more stable display emitters that meet demanding Rec.2020 standards and withstand 150 °C.

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Reference
Maithili K. Rao et al., “Tackling toxicity and stability using eco-friendly metal-halide ion substituted perovskite nanocrystals for advanced display color conversion,” Chemical Engineering Journal, 494 (2024) 152918. https://doi.org/10.1016/j.cej.2024.152918