Lumidox® LED Arrays

Lumidox® LED Arrays

By utilizing new breakthroughs in LED technology, Analytical Sales&Services is able to provide the next generation Lumidox II with higher optical/radiation power than ever before. Lumidox II offers over 200 complementary photonic devices with different wavelengths, amplitudes, and sizes. It takes a few hours, now it only takes a few minutes. Reduce the photochemical reaction time by up to 40 times while maintaining the same yield.

The Lumidox II controller is internally manufactured. The optical power level is provided in integer form that is easy to read and calculate. Simply scroll through the menu to select the desired output. Provides a car lighting timer and an automatic countdown to turn off the timer.

The array and lighting fixtures are custom tuned internally and offer 5 individually calibrated and configured optical power levels. Arrays and luminaires are not included in the controller, and their calibration data is stored on the board, allowing users to use different arrays through a single controller.

Lumidox® LED Arrays

We offer instruments with the following wavelengths:
UV365、UV375、UV385、UV395、UV405、 420 (purple), 445 (indigo), 470 (blue), 505 (cyan), 527 (green), 590 (amber), 630 (red), 660 (deep red), 730 (infrared), white

Analytical Sales&Services is pleased to offer the second-generation Lumidox in 660 nm and 730 nm versions for academic research focused on deep red/near-infrared light (wavelengths between 650-740 nm) ® Product. By incorporating these wavelengths into their products, Analytical Sales can achieve more potential applications than ever before.

The use of near-infrared wavelength (730 nm) is particularly interesting, and one potential application is to drive photocatalytic reactions. By utilizing 730 nm infrared light in this way, German researchers were able to synthesize metal nanoparticles (MNP) using polyoxometalates as photocatalysts. This type of work may have a significant impact on the field of nanobiotechnology.

Metal nanoparticles are highly toxic to living cells. Although the use of these materials may be harmful to humans, due to their high level of antibacterial activity, it is possible to use them as novel antibiotics. An article in the Journal of Nanobiotechnology summarizes and discusses the antibacterial mechanisms of various MNPs.

Another major application of the 730 nm wavelength is in the field of plant science. The photosynthesis that occurs in most plant life on Earth absorbs light in the purple/blue and red ranges. That's why most plants are green to us - because they can't absorb light in the green range, these wavelengths will reflect back to us, and our eyes will feel 'green'. As described in the study of photosynthesis, scientists conducting agricultural research investigated the amount of chlorophyll fluorescence and leaf photosynthesis at different wavelengths (such as 680 and 730 nanometers).

Another study focused on the distribution of 660 nm and 730 nm radiation in the maize canopy. Scientists have placed a series of sensors throughout and inside the corn crop, and measured the 730 nm radiation received by the crop at different times of the day. In the middle of the day, crops receive relatively stable levels of 730 nm radiation. However, in the early morning and evening, when the sun was lower on the horizon, they observed an increase in 730 nm radiation compared to the radiation observed at noon. At the point where the 680 nm wavelength is immediately absorbed by the leaves, the 730 nm wavelength scatters, allowing it to penetrate deeper into the maize crop canopy, greatly enriching it. Scientists can now study the implications of these findings by utilizing high-power artificial 730 nm light,

Another application may be in the field of laser irradiation for cancer tumors, also known as photodynamic therapy. In particular, a study published in the journal "Organic Metals" focuses on the photodynamic therapy effect of iridium complexes under 730 nm continuous wave laser irradiation. This type of research has enormous significance in the field of cancer research. It is possible to deliver iridium complexes to tumor cells through injection, and then apply near-infrared (730nm) continuous wave laser radiation to prevent or even reverse tumor growth. We are currently conducting in vivo studies on rat and mouse specimens.