Luminescence Enhancement of Mn4+-Activated Fluorides via a Heterovalent Co-Doping Strategy for Monochromatic Multiplexing.

Mn4+ non-equivalent doped fluorides with high color purity red emission and relatively short decay time are crucial for wide color gamut displays and emerging applications, whereas the low quantum efficiency (QE) restrains their further applications. Herein, the luminescence of Mn4+ non-equivalent doped fluoride K2NaAlF6:Mn4+ (KNAF:Mn4+) is significantly enhanced via a heterovalent co-doping strategy, where the luminescence intensity is obviously increased by ∼85%, but the decay time is almost unchanged. The experimental characterization and density functional theory (DFT) calculations provide an understanding of the luminescence enhancement mechanism of heterovalent co-doping, which is enabled by simultaneously improving the stability of Mn4+ and reducing the number of quenching centers (defects and impurities). Combining the short-decay-time (τ = 4.03 ms) emission KNAF:Mn4+, Mg2+ and long-decay-time (τ = 9.23 ms) emission K2SiF6:Mn4+, a novel monochromatic multiplexing mode in the millisecond order is presented, which can be decoded not only in high-efficiency by a digital camera but also with a high security. This work provides a new optical multiplexing for the information security applications and also inspires the design of high-efficiency Mn4+-activated luminescent materials.

[1]  Liyi Li,et al.  Persistent luminescence induced by the introduction of multi-valent Mn ions in K2LiBF6 (B = Al, Ga and In) fluoride phosphors , 2021, Chemical Engineering Journal.

[2]  B. Richards,et al.  Anticounterfeiting Labels with Smartphone‐Readable Dynamic Luminescent Patterns Based on Tailored Persistent Lifetimes in Gd2O2S:Eu3+/Ti4+ , 2021, Advanced Materials Technologies.

[3]  Yong‐Jin Pu,et al.  The effect and mechanism of different charge compensation on the luminescent properties of Eu-doped BaSiO3 phosphor calcined in air with self-reduction , 2021 .

[4]  S. Ye,et al.  Constructing perovskite-like oxide CsCa2Ta3O10: Yb, Er@Cs(PbxMn1-x)(ClyBr1-y)3 perovskite halide composites for five-dimensional anti-counterfeiting barcodes applications , 2021 .

[5]  Qinyuan Zhang,et al.  Mn4+ doped narrowband red phosphors with short fluorescence lifetime and high color stability for fast-response backlight display application , 2021 .

[6]  Amin Abdollahi,et al.  Photoluminescent and Chromic Nanomaterials for Anticounterfeiting Technologies: Recent Advances and Future Challenges. , 2020, ACS nano.

[7]  Lirong Zheng,et al.  Host Differential Sensitization toward Color/Lifetime-Tuned Lanthanide Coordination Polymers for Optical Multiplexing. , 2020, Angewandte Chemie.

[8]  Jun Lin,et al.  Lanthanide-activated nanoconstructs for optical multiplexing , 2020 .

[9]  Chonggeng Ma,et al.  High-security-level multi-dimensional optical storage medium: nanostructured glass embedded with LiGa5O8: Mn2+ with photostimulated luminescence. , 2020, Light, science & applications.

[10]  Fengjia Fan,et al.  Reversible 3D laser printing of perovskite quantum dots inside a transparent medium , 2020, Nature Photonics.

[11]  E. Song,et al.  Ammonium salt conversion towards Mn4+ doped (NH4)2NaScF6 narrow-band red-emitting phosphor , 2019, Journal of Alloys and Compounds.

[12]  Zhonghua Deng,et al.  Moisture‐Resistant Mn 4+ ‐Doped Core–Shell‐Structured Fluoride Red Phosphor Exhibiting High Luminous Efficacy for Warm White Light‐Emitting Diodes , 2019, Angewandte Chemie.

[13]  Qiang Zhao,et al.  Engineering Luminescence Lifetimes of Cu(I) Complexes for Optical Multiplexing , 2018, Advanced Optical Materials.

[14]  T. Senden,et al.  Quenching of the red Mn4+ luminescence in Mn4+-doped fluoride LED phosphors , 2018, Light: Science & Applications.

[15]  C. Detavernier,et al.  Red Mn4+-Doped Fluoride Phosphors: Why Purity Matters. , 2018, ACS applied materials & interfaces.

[16]  R. Xie,et al.  Achieving High Quantum Efficiency Narrow-Band β-Sialon:Eu2+ Phosphors for High-Brightness LCD Backlights by Reducing the Eu3+ Luminescence Killer , 2017 .

[17]  Yu Wang,et al.  Binary temporal upconversion codes of Mn2+-activated nanoparticles for multilevel anti-counterfeiting , 2017, Nature Communications.

[18]  Xiaobao Yang,et al.  Highly Efficient and Stable Narrow-Band Red Phosphor Cs2SiF6:Mn4+ for High-Power Warm White LED Applications , 2017 .

[19]  S. Ye,et al.  Highly Efficient and Thermally Stable K3AlF6:Mn4+ as a Red Phosphor for Ultra-High-Performance Warm White Light-Emitting Diodes. , 2017, ACS applied materials & interfaces.

[20]  Ru‐Shi Liu,et al.  Highly efficient non-rare-earth red emitting phosphor for warm white light-emitting diodes , 2014, Nature Communications.

[21]  D. Wang,et al.  Deep red phosphors SrAl12O19:Mn4+,M (M = Li+, Na+, K+, Mg2+) for high colour rendering white LEDs , 2013 .

[22]  J. C. Schön,et al.  Experimental and theoretical study on Raman spectra of magnesium fluoride clusters and solids. , 2012, The Journal of chemical physics.

[23]  M. Brik Influence of chemical bond length changes on the crystal field strength and “ligand–metal” charge transfer transitions in Cs2GeF6 doped with Mn4+ and Os4+ ions , 2007 .

[24]  N. Bjerrum,et al.  Raman study of the hexafluoroaluminate ion in solid and molten FLINAK. , 2000, Inorganic chemistry.

[25]  H. Bode,et al.  Über eine neue Darstellung des Kalium‐hexafluoromanganats(IV) , 1953 .