Two-photon (TP) three-dimensional(3D) solid matrices have potential applications in high density optical data reading and storage, infrared-pumped visible displays, lasers, etc.
More recent experimental and theoretical studies of TP materials mainly focused on the microworld, for instance semiconductor nanocrystals and organic molecules. For many real applications, low-dimensional materials cannot meet the requirements of stability and durability. Hence, 3D solid matrices that possess stable and tunable TP properties are required.
Colloidal quantum dots (CQDs), a typical zero-dimensional material with a quantized energy structure, have been widely used in optoelectronic fields. However, for a long time, most of the studies were focused on the linear optical region of CQDs and their preparation.
Recently, researchers at Shanghai Institute of Optics and Fines Mechanics (SIOM) of Chinese Academy of Sciences have presented a facile method for preparing a homogeneously doped CQD-silica gel glass (CQD-SGG) while maintaining excellent nanoscale TP properties. Characterization using an open-aperture Z-scan technique shows that the solid matrices exhibited significant TP optical properties with a TP absorption coefficient of (9.41 ± 0.39) × 10?2 cm GW?1 and a third-order nonlinear figure of merit of (7.30 ± 0.30) × 10?14 esu cm. The study was published in Nanoscale.
They also systematically studied the TP behavior of the CQD-SGG, as a function of temperature, in the range of 300 to 523 K. It was found that the CQD-SGG can maintain stable TP PL below the synthesis temperature of the CdTe/CdS CQDs.
Additionally, the results suggest that the TP PL quenching occurs firstly through the formation of carrier trap sites caused by the lattice mismatch. With further increase of the thermal treatment temperature, the ligands on the CQD surfaces are easily detached, leading to substantial surface defects.
This work indicates that such CQD-SGG will provide another promising candidate for investigating TP optical properties and applications in novel photoelectronic devices.
This work was supported financially by the NSFC, the Shanghai Rising-star Program, the Youth Innovation Promotion Association of Chinese Academy of Sciences, and the Shanghai Science and Technology Committee.