Time-dependent Phosphorescence Color of Carbon Dots in Binary Salt Matrices through Activations by Structural Confinement and Defects for Dynamic Information Encryption

The emergence of time-dependent phosphorescence color (TDPC) materials has taken information encryption to high-security levels. However, due to the only path of exciton transfer, it is almost impossible to obtain TDPC for chromophores with a single emission center. Theoretically, in inorganic-organic composites, the exciton transfer of organic chromophores depends on the inorganic structure. Here, we assign two structural effects to inorganic NaCl by metal (Mg²⁺ or Ca²⁺ or Ba²⁺) doping, which triggers the TDPC performance of carbon dots (CDs) with a single emission center. The resulting material is used for multi-level dynamic phosphorescence color 3D coding to achieve information encryption. The structural confinement activates the green phosphorescence of CDs; while the structural defect activates tunneling-related yellow phosphorescence. Such simply doped inorganic matrices can be synthesized using the periodic table of metal cations, endowing chromophores with tremendous control over TDPC properties. This demonstration extends the design view of dynamic luminescent materials.     

Pressure-Tuned Multicolor Emission of 2D Lead Halide Perovskites with Ultrahigh Color Purity

The chemical diversity and structural flexibility of lead halide perovskites (LHPs) offer tremendous opportunities to tune their optical properties through internal molecular engineering and external stimuli. Herein, we report the wide-range and ultrapure photoluminescence emissions in a family of homologous 2D LHPs, [MeOPEA]₂PbBr_4−4xI_4x (MeOPEA=4-methoxyphenethylammonium; x=0, 0.2, 0.425, 0.575, 1) enabled through internal chemical pressure and external hydrostatic pressure. The chemical pressure, induced by the C−H⋅⋅⋅π interactions and halogen doping/substitution strengthens the structural rigidity to give sustained narrow emissions, and regulates the emission energy, respectively. Further manipulation of physical pressure leads to wide-range emission tuning from 412 to 647 nm in a continuous and reversible manner. This work could open up new pathways for developing 2D LHP emitters with ultra-wide color gamut and high color purity which are highly useful for pressure sensing.     

铜箔碳掺杂对化学气相沉积生长的六方氮化硼中含碳色心的高效制备及其调控

缺陷和掺杂对材料的力学、 电子和光学性能均具有重要影响. 六方氮化硼(Hexagonal Boron Nitride, hBN)由于具有a6 eV 的宽带隙, 其中的点缺陷可以在带隙内产生发射波长覆盖近紫外-近红外波段的室温稳定发光的深能级色心, 是量子光源等光学的理想载体. 近年来的实验和理论研究表明, 碳缺陷是h-BN 可见光波段单光子发射的主要可能来源之一; 然而, 当前对h-BN 中碳缺陷的有效制备和精确调控仍存在挑战. 本文报道了一种有效方法, 通过在化学气相沉积(Chemicalvapordeposition, CVD) 过程中预先控制用于催化生长h-BN 的铜箔衬底中的碳含量, 制备得到了不同密度的零声子发射(Zero-phononlines, ZPL)波长位于626±3 nm 的色心; 此外, 我们还观察到气氛退火对色心发光显著的调控作用. 该色心优良的单色性和可调控性有助于推动基于h-BN 的量子光源和光子学器件的潜在应用, 对理解h-BN 中碳缺陷的形成亦具有重要意义.