Lasers and the electromagnetic spectrum

The color of light you choose will have a big effect on what your laser beam can do. Let’s discuss various colors of light, both visible and invisible, to get an overview of what each is good for and what limitations each may have. After all, choosing the right color is the key to really making your laser shine.

Radio

Radio waves are essentially useless for lasers. Sure, they get through the air okay, but diffraction makes them almost impossible to focus enough to cause damage. So without further ado, we’ll move on.

Microwaves

Microwaves, at least, focus better than radio waves. They still don’t focus well enough to make practical weapons - at least not if your intent is cooking or burning or blasting your enemy. They are useful at projecting destructive currents into electronic circuits. Such high power microwave devices operating in a counter-electronics role are usually considered a different class of weapon than lasers, so we will leave them for now.

Terahertz waves

Terahertz waves are all the rage these days for remote scanning and a new window for material spectroscopy. Unfortunately, they are absorbed by the air within a few tens of meters, so they are a poor choice for a weapon.

Far infrared

Far infrared is a sort of orphan band of the electromagnetic spectrum, because it is hard for us to get sources and detectors in this range. As a result, we don’t have a lot of experience with what it can do. In principle, your high-tech sci-fi society could be able to make fiercely high power far infrared lasers. But they’re still not a good choice for a weapon because the diffraction limit makes them hard to focus to damaging intensities without huge focal apertures and they’d have bad issues with cascade breakdown of the air.

Long-wave infrared

This is the electromagnetic band where most thermal radiation from room-temperature and body-temperature objects occur. When someone is seeing heat with infrared vision, this is the color they are seeing with. The atmosphere is quite transparent to long-wave infrared radiation. Unfortunately, these long wavelengths are still difficult to focus at any useful distance, and they tend to cause cascade breakdown in the air when high powers are put into tight focal spots. The main reason they pop up in talking about lasers is that one of the first kinds of high power lasers, and still one of the cheapest and simplest to build, is the carbon dioxide laser which operates in the long-wave infrared.

Mid-wave infrared

A lot of the mid-wave infrared spectrum is absorbed quickly by air. However, there is a “window” between 3.5 and 4 μm where the light can get through. This window was investigated by early laser weapon designers, using chemical deuterium fluoride lasers. Chemical laser weapons were nasty, toxin-spewing, noisy monstrosities of machines with abysmal beam quality and long logistics chains to supply their highly toxic, corrosive, flammable, and explosive chemicals. And even when they were the only game in town, the deuterium fluoride laser was replaced as soon as they could by chemical oxygen iodine lasers that at least operated in the near infrared and so could be focused three times as far. Today we have far better choices, so don’t expect mid-wave infrared lasers to get much love.

Short-wave infrared

Short-wave infrared is a good choice when you are looking for a color of light that focuses well, can get through air, can maintain a tight focus without two-photon ionization messing it up, and that won’t pose a severe blinding hazard to anyone nearby. It is the shortest wavelength (and thus longest ranged) color of infrared that is eye-safe. You won’t get eye-safe colors again until you are up into the ultraviolet.

Some modern lasers can output high power short-wave infrared beams, primarily fiber lasers.