Aqueous synthesis of 79% efficient AgInGaS/ZnS quantum dots for extremely high color rendering white light-emitting diodes

doi:10.1016/j.jmst.2022.06.035

Abstract

Abstract:

Over the past few decades, I-III-VI quantum dots (QDs) have attracted considerable attention due to their large Stokes shifts, good eco-friendliness, and wide tunable emissions. In this work, a facile microwave-assisted aqueous route using glutathione (GSH) and citric acid (CA) as dual stabilizers is introduced to synthesize AgInGaS/ZnS (AIGS/ZnS) core/shell QDs. An exceptional photoluminescence quantum yield (PL QY) as high as 79% is successfully achieved, boosting the best performance of water-dispersible AIGS QDs. By varying the Ag/Ga ratio, the PL peak wavelength can be tuned from 547 to 616 nm, and luminescent hydrogel films with different colors are obtained by embedding AIGS/ZnS QDs in polyacrylamide/poly-vinyl alcohol (PAAm/PVA) hydrogels. The white light-emitting diode (WLED) with a high color rendering index (CRI) of 92.1 (R₉=92.0) and a correlated color temperature (CCT) of 3022 K is fabricated using QDs-PAAm/PVA hydrogel films in combination with a blue InGaN LED chip, indicating that the as-prepared QDs are competitive color-conversion materials for WLEDs.

Key words: AgInGaS/ZnS, Aqueous synthesis, Quantum dots, White LEDs

Zhe Hu, Hanxu Lu, Wenjie Zhou, Jinxin Wei, Hanqing Dai, Hong Liu, Zhiyong Xiong, Fengxian Xie, Wanlu Zhang, Ruiqian Guo. Aqueous synthesis of 79% efficient AgInGaS/ZnS quantum dots for extremely high color rendering white light-emitting diodes[J]. J. Mater. Sci. Technol., 2023, 134: 189-196.

Figures/Tables 8

Scheme 1. Schematic illustration for the QDs-PAAm/PVA fluorescent hydrogel films and their application in WLED.

Fig. 1. TEM and HRTEM images and histograms of the size distribution (inset) of (a, b) AIGS and (c, d) AIGS/ZnS QDs.

Fig. 2. Comparison of (a) XRD patterns, (b) XPS spectra, and (c) high-resolution XPS spectra of AIGS and AIGS/ZnS QDs.

Fig. 3. (a) UV-vis absorption spectra and the PL spectra (λex = 500 nm) with several batches of Zn-stock injection, (b) peak positions and PL QY of different batches of Zn-stock injection, and (c) PL decay curves and digital photographs under UV-light irradiation (inset) of AIGS and AIGS/ZnS QDs.

Table 1. Fitted parameters for PL decay curves of AIGS and AIGS/ZnS QDs.

Sample	τ₁ (ns)	A₁ (%)	τ₂ (ns)	A₂ (%)	τ_av (ns)
AIGS	99.23	33.11	532.25	66.89	495.66
AIGS/ZnS	207.32	36.40	583.52	63.60	519.95

Fig. 4. (a) UV-vis absorption spectra and the PL spectra (λex = 500 nm) of AIGS/ZnS QDs under different refluxing time. PL spectra (λex = 500 nm) of AIGS/ZnS QDs with different (b) refluxing temperatures, (c) pH values, and (d) GSH dosages.

Fig. 5. (a) UV-vis absorption spectra, normalized PL spectra (λex = 500 nm) and the corresponding digital photographs under UV-light irradiation (inset) of AIGS/ZnS QDs synthesized at different molar ratios of Ag/Ga. (b) Schematic diagram of the bandgap broadened by Ag proportion decrease.

Fig. 6. (a) PL spectra and (b) the corresponding digital photographs of green and red QDs-PAAm/PVA films under UV-light irradiation. (c) Electroluminescent spectrum and (d) CIE color coordinate of the WLED based on both green and red QDs-PAAm/PVA hydrogel films at a drive current of 100 mA.

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