High-brightness green CdSe/ZnS quantum dots stimulated by solar-blind deep-ultraviolet light in optical wireless communications.

Ultraviolet-based optical wireless communication (OWC) is emerging as a significant technology for the next-generation secure communication, particularly within the solar-blind spectra. In this study, we have synthesized two types of green-emitting II-VI family colloidal quantum dots (QDs), specifically ZnCdSe/ZnS and CdSe/CdZnS/ZnS QDs, which are stimulated by ultraviolet (UV) and solar-blind deep-ultraviolet (DUV) light, respectively. With a transmission distance of 1.5 m, the maximum data rate of ZnCdSe/ZnS QDs reaches 40 Mb/s, which is below the forward-error-correction (FEC) limit (3.8 × 10-3) when excited by 385-nm UV light. However, both brightness and bit error rate are significantly deteriorated when excited by 280-nm DUV light. Conversely, 28 and 24 Mb/s were attained using CdSe/CdZnS/ZnS QDs under UV and DUV excitation, respectively. Our studies on light-conversion and communication capabilities of green QDs within the DUV OWC system may provide valuable insights for subsequent research in the field.

Turbidity-tolerant underwater wireless optical communications using dense blue-green wavelength division multiplexing.

Underwater wireless optical communication (UWOC) has demonstrated high-speed and low-latency properties in clear and coastal ocean water because of the relatively low attenuation 'window' for blue-green wavelengths from 450 nm to 550 nm. However, there are different attenuation coefficients for transmission in ocean water at different wavelengths, and the light transmission more seriously deteriorates with fluctuations in the water turbidity. Therefore, traditional UWOC using a single wavelength or coarse blue-green wavelengths has difficulty tolerating variations in water turbidity. Dense wavelength division multiplexing (WDM) technology provides sufficient communication channels with a narrow wavelength spacing and minimal channel crosstalk. Here, we improve the UWOC in clear and coastal ocean water using dense blue-green WDM. A cost-effective WDM emitter is proposed with directly modulated blue-green laser diodes. Dense wavelength beam combination and collimation are demonstrated in a 20-metre underwater channel from 490 nm to 520 nm. Demultiplexing with a minimum channel spacing of 2 nm is realized by an optical grating. Remarkably, our WDM results demonstrate an aggregate data rate exceeding 10 Gbit/s under diverse water turbidity conditions, with negligible crosstalk observed for each channel. This is the densest WDM implementation with a record channel spacing of 2 nm and the highest channel count for underwater blue-green light communications, providing turbidity-tolerant signal transmission in clear and coastal ocean water.

Graphdiyne-deposited microfiber structure all-optical modulator at the telecommunication band.

All-optical modulator is a crucial device in next generation of all-optical communications, interconnects, and signal processing. Here, we demonstrate an all-optical phase modulator with graphdiyne (GDY)-deposited microfiber structure. The phase shift of the signal light can be readily controlled by pump light by thermo-optic effect. This all-optical modulator can achieve a phase shift slope of 0.0296 π·mW-1 and a rising time of 5.48 ms at 25 Hz (3 ms, 50 Hz). Modes distributions in GDY-deposited microfiber at different wavelength are numerical analyzed and the normalized phase conversion efficiency of GDY are calculated. The results show that GDY has a considerable normalized phase conversion efficiency of 0.1644 π·mW-1·mm-1, which is higher than that of graphene, MXene and WS2 based all-optical modulators. This work proves the potential of GDY in all-optical modulator device at telecommunication band and provides a support to all-optical signal processing systems.