4.7 Article

Ligand Effects on Photoluminescence and Electroluminescence of Silicon Quantum Dots for Light-Emitting Diodes

Journal

ACS APPLIED NANO MATERIALS
Volume 5, Issue 6, Pages 7787-7797

Publisher

AMER CHEMICAL SOC
DOI: 10.1021/acsanm.2c00811

Keywords

nanocrystal; nanoparticle; HSQ; POSS; QLED

Funding

  1. Japan Society for the Promotion of Science (JSPS) [GR073]
  2. JSPS [15H02001, 19H02556]
  3. PRESTO Structure Control and Function Program of the Japan Science and Technology Agency (JST)
  4. JKA through its promotion funds from AUTORACE [2019-M188]

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Colloidal silicon quantum dots (SiQDs) were synthesized with different ligand coverages and assembled into LEDs. The study found that ligand coverage significantly affected the performance of SiQD LEDs, especially in terms of electroluminescence turn-on voltage and external quantum efficiencies.
Colloidal silicon quantum dots (SiQDs) may potentially minimize the environmental impact of commercial LEDs and advance nextgeneration light sources. Many studies have investigated the optical properties of SiQDs prepared by chemical synthesis, but the essential features of surface ligands have not fully been understood. Characterizing surface ligands should have a significant impact on optoelectronic research and ensuing applications. In this study, colloidal SiQDs were synthesized by pyrolyzing hydrogen silsesquioxane, followed by thermal hydrosilylation with 1-decene. Decylterminated SiQDs exhibited photoluminescence (PL) in a wavelength of 730 nm and PL quantum yields (QYs) of up to 38%. Seven decyl-terminated SiQDs with different ligand coverages were synthesized by varying the reaction time of hydrosilylation between 10 min and 9 h, and then these SiQDs were assembled into LEDs. The PL spectra, PLQYs, and performance of the SiQD LEDs were evaluated as a function of the decyl-ligand coverage. The PL properties (i.e., peak wavelength and PLQY) were insensitive to changes in decyl-ligand coverage, whereas the LED performance changed significantly. In particular, a 2-fold difference in decyl-ligand coverage exhibited a 4-fold difference in electroluminescence (EL) turn-on voltage and a 17-fold difference in EL external quantum efficiencies. In addition, the LED performance was characterized by quantifying the relationship between ligand coverage, the number of bonding sites, and the surface areas of the ligands. At greater than 25% coverage, the total surface area of the decyl-ligands was significantly larger than that of a single SiQD, and when decyl-ligands and Si-O groups covered 50% of the surface, the insulation effect impaired the LED performance. Therefore, ligand coverage significantly affected the performance of SiQD LEDs. Although this study was limited to decyl-terminated SiQDs, the same method can be applied to other ligands to further improve LED efficiency of next-generation light sources in displays, lighting, and biomedical imaging.

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