Ultraviolet Light

“Ultraviolet (UV) light is electromagnetic radiation with a wavelength shorter than that of visible light, but longer than x-rays, in the range 10 nm to 400 nm, and energies from 3 eV to 124 eV. It is so named because the spectrum consists of electromagnetic waves with frequencies higher than those that humans identify as the color violet.” Source.

There are several ways of subdividing the UV electromagnetic spectrum. Most common is:

Name	Short	Wavelength	Photon energy
Ultraviolet A, long wave, or black light	UVA	400 nm–320 nm	3.10–3.94 eV
Ultraviolet B or medium wave	UVB	320 nm–280 nm	3.94–4.43 eV
Ultraviolet C, short wave, or germicidal	UVC	280 nm–100 nm	4.43–12.4 eV

There are several ways of producing UV light, that include natural sources (Eg. the Sun) or artificial sources (UV bulbs, UV tubes, N2 Lasers, etc).

I have tested two UV Light tubes: a black light UV tube, and a germicidal UV tube. There two correspond to UVA and UVC spectrum.

UVA
The wavelength is in the range of 400 nm and 320 nm. I have a 6W “blacklight tube”. Looking at powered tube you barely see anything, but putting a piece of white paper shows powerful fluorescence. The second picture below shows this phenomenon:

The reason for this is that my UVA tube emits long wave UV radiation and very little visible light.
In the third picture, the glass ball is an uranium doped glass. It shows greenish fluorescence when exposed to UV. See an article on this topic, here.

This type of tube looks black when non energized, as the deep-bluish-purple glass called Wood’s glass, is a nickel-oxide–doped glass, which blocks almost all visible light above 400 nanometers.
Unlike the other UV subdivisions with shorter wavelength, the UVA emits lower energy radiation, that doesn’t cause sunburns or skin cancer. Instead, UVA is capable of causing damage to collagen fibers and destroying vitamin A in skin.

UVC
I got these tubes at a fair price on Ebay. They were manufactured to be used in germicidal applications. Most of the light they produce is in the 280 nm–100 nm spectrum. The sun is a natural source for UVC radiation. Some of the UVB and UVC radiation is responsible for the generation of the ozone layer. After running my UVC tubes for a while, ozone smell could be detected in the air surrounding the tube.

In this video you can see that if the magnetic field moves, the plasma moves in such a way that magnetic field lines cannot slide across the plasma.

UVC rays are the highest energy, most dangerous type of ultraviolet light. Unshielded exposure of the skin or eyes to UVC light sources is quite dangerous. It can produce DNA damage that leads to skin cancer, since it penetrates the skin, so protection is required.

Power source
Solution 1:
To power these tubes you need a high voltage source. A simple solution is to use an inverter. You can also build one, using a power transistor (2n3055) and a flyback transformer ferrite core:

The resistors need to be at least 5W, and the transistor can be a 2n3055.
The primary consists of 30 turns, for the feedback you’ll need 15turns and 250 turns of secondary, all concentric. You might need to be able to swap feedback (or primary) connections in case of wrong phase polarity.

Solution 2:
Another way of building the power source is without a feedback coil, but instead a 555 timer to trigger the power transistor. Here are the schematics:

Instead of the MPSA42 / MPSA92, you can use any other generic PNP/NPN pair of 0.5A minimum current.
The Mosftet (IRF540) will be needing a heatsink. You can use a different power mosfter or a power BJT transistor instead (eg. 2n2055).
The secondary can be winded manually or you can use a flyback secondary.
The advantage of this circuit is that you can adjust the frequency using the pot.

The next few days, I’ll be publishing an article on various high voltage sources, so we’ll see more on these later.

Radu Motisan

Laser photography

A few days ago I tried to record the pure color of a laser beam. I’ve used two lasers, a red one, and a green one. Unfortunately the camera was exposed too much – or the laser was too powerful, since the CCD got fried in two spots. So don’t do this with your camera, the risk is too high. Better enjoy the pictures below, it’s safer.

Click on the pictures below for the HiRes version:

Radu Motisan

100mW Burning Red Laser

Now that the laser diodes are everywhere, I wonder how many of you remember how a HeNe laser looks like. For me it was the first laser I’ve seen, and it was at the age of 14 (back in April 1997). Up to that point, I was aware of lasers only from SciFi movies. In 1997, I finally had one right in front of me. It was in a physics laboratory, at the Mihai Eminescu Highschool, Satu Mare. There I’ve spent the next 4 years of my life. This laser was a HeNe laser. Big, somehow noisy, and for the 1mw output used a big power source. But it was a laser and followed the guidelines! A laser (Light Amplification by Stimulated Emission of Radiation) is a device which uses a quantum mechanical effect, stimulated emission, to generate a coherent beam of light from a lasing medium of controlled purity, size, and shape. The output of a laser may be a continuous, constant-amplitude output (known as CW or continuous wave), or pulsed, by using the techniques of Q-switching, modelocking, or gain-switching. In pulsed operation, much higher peak powers can be achieved. A laser medium can also function as an optical amplifier when seeded with light from another source. The amplified signal can be very similar to the input signal in terms of wavelength, phase, and polarisation; this is particularly important in optical communications. The verb “to lase” means “to produce coherent light” or possibly “to cut or otherwise treat with coherent light”, and is a back-formation of the term laser. Common light sources, such as the incandescent light bulb, emit photons in almost all directions, usually over a wide spectrum of wavelengths. Most light sources are also incoherent; i.e., there is no fixed phase relationship between the photons emitted by the light source. By contrast, a laser generally emits photons in a narrow, well-defined, polarized, coherent beam of near-monochromatic light, consisting of a single wavelength or hue. Over the time solid state lasers have been developed: these devices emit coherent light, at the cost of very little electrical power. Now laser diodes can be found almost everywhere, so I thought it is time to try to get one myself. So I’ve purchased a 100mW laser diode from ebay. It came with the driver circuit, ready for power up. Using that, I’ve created a simple aluminum housing, to keep the device packed together with the batteries, for easier use. I’m going to show that here: Materials used: 1. The laser diode with its driver circuit (~26$) This is a 100mw Pulsed red (655nm) laser diode. 2. Rechargeable 2700mAh 4 Battery pack (~20$) This pack provides 4×1.2V = 4.8V @ 2700mAh 3. Suitable shape metal piece (free) 4. Long shape aluminum can with top removed (free) 5. Adhesive tape, some screws and some tools A few steps and we are done I’ve packed all the laser components on the small metal board. Under the laser driver and the batteries I’ve added a plastic layer to prevent the electronic components from getting in contact with the metal surface. Next I drilled a few holes in the aluminum can to be able to fix some screws, and I covered it in black tape so it would look better and would get an extra strength. I’ve also added a switch between the batteries and the laser driver circuit. The laser diode got an improvised support, from a small plastic pipe as seen in the picture. This also has a screw to fix it to the metal surface. I pushed the components inside the aluminum housing, and fixed the screws. Now that everything is done, we can test the overall look and feel of this little device. Adjusting the output lens, allows focusing the beam to a tiny spot, hot enough to instantly burn black colored materials. Why black? Because black materials do not reflect light, they absorb it. The result is accumulated energy in the form of heat. To the right there are several other hires photos with my red laser. All the pictures are real, as recorded with my camera. I’ve also added some pictures with a 5mW green laser, even if it’s not related to this project. Just a little light show, hope you like it. Radu Motisan