The Deep Ultraviolet (DUV)  Parallel Photoreactor exhibits notable usage characteristics and advantages in ultraviolet (UV) experiments. Firstly, it employs a high-energy DUV light source and achieves efficient photochemical reactions through microchannel reactors, effectively exciting molecules or atoms within the samples and significantly accelerating reaction rates. The instrument boasts high optical transparency and efficient photon absorption capabilities, enabling high-efficiency reactions without the need for expensive photocatalysts, thereby reducing experimental costs.

Secondly, the DUV Parallel Photoreactor provides high and uniform light intensity, with light intensity reaching nearly 500mw/cm² and light attenuation less than 5% per year, ensuring the stability and reproducibility of experimental results. Additionally, the instrument supports the selection of multi-wavelength light sources, covering a wavelength range of 365～975nm to meet diverse experimental requirements.

Moreover, the instrument features precise temperature control through an external temperature control device, with a temperature range of 0-50℃, ensuring optimal reaction conditions. Its multi-position design allows simultaneous processing of multiple samples, enhancing experimental efficiency. Meanwhile, equipped with a cooling water supply device, the instrument ensures the stable operation of the light source over extended periods, making it suitable for continuous operation experiments.

In UV experiments, the DUV Parallel Photoreactor stands out with its high efficiency, stability, reproducibility, as well as advantages such as multi-wavelength light sources and precise temperature control, rendering it an indispensable experimental apparatus in fields such as chemistry, materials science, and biomedicine.