Can special eyeglasses let you see invisible radiation?

I’ve read reference to “Smart” eyeglasses or contact lenses that can present more than just the visible portion of the electromagnetic spectrum. I’m wondering if you have any sources for these type of devices that are available to we civilians. — GJ, Wells, Nevada

Since our eyes are only sensitive to light that’s in the visible range, any “smart” optical system would have to present whatever it detects as visible light. That means it has to either shift the frequencies/wavelengths of non-visible electromagnetic radiation into the visible range or image that non-visible radiation and present a false-color reproduction to the viewer. Let’s consider both of these schemes.

The first approach, shifting the frequencies/wavelengths, is seriously difficult. There are optical techniques for adding and subtracting optical waves from one another and thereby shifting their frequencies/wavelengths, but those techniques work best with the intense waves available with lasers. For example, the green light produced by some laser pointers actually originated as invisible infrared light and was doubled in frequency via a non-linear optical process in a special crystal. The intensity and pure frequency of the original infrared laser beam makes this doubling process relatively efficient. Trying to double infrared light coming naturally from the objects around you would be extraordinarily inefficient. In general, trying to shift the frequencies/wavelengths of the various electromagnetic waves in your environment so that you can see them is pretty unlikely to ever work as a way of seeing the invisible portions of the electromagnetic spectrum.

The second approach, imaging invisible portions of the electromagnetic spectrum and then presenting a false-color reproduction to the viewer, is relatively straightforward. If it’s possible to image the radiation and detect it, it’s possible to present it as a false-color reproduction. I’m talking about a camera that images and detects invisible electromagnetic radiation and a computer that presents a false-color picture on a monitor. Imaging and detecting ultraviolet and x-ray radiation is quite possible, though materials issues sometimes makes the imaging tricky. Imaging and detecting infrared light is easy in some parts of the infrared spectrum, but detection becomes problematic at long wavelengths, where the detectors typically need to be cooled to extremely low temperatures. Also, the resolution becomes poor at long wavelengths.

Camera systems that image ultraviolet, x-ray, and infrared radiation exist and you can buy them from existing companies. They’re typically expensive and bulky. There are exceptions such as near-infrared cameras — silicon imaging chips are quite sensitive to near infrared and ordinary digital cameras filter it out to avoid presenting odd-looking images. In other words, the camera would naturally see farther into the infrared than our eyes do and would thus present us with images that don’t look normal.

In summary, techniques for visualizing many of the invisible portions of the electromagnetic spectrum exist, but making them small enough to wear as glasses… that’s a challenge. That said, it’s probably possible to make eyeglasses that image and detect infrared or ultraviolet light and present false-color views to you on miniature computer monitors. Such glasses may already exist, although they’d be expensive. As for making them small enough to wear as contact lenses… that’s probably beyond what’s possible, at least for the foreseeable future.

Eyeglasses bend an object’s light rays so that your eye can focus them properly.

How do glasses work and what is the physics behind them? — SDM, Missouri

Like a camera, your eye collects light from the scene you’re viewing and tries to form a real image of that scene on your retina. The eye’s front surface (its cornea) and its internal lens act together to bend all the light rays from some distant feature toward one another so that they illuminate one spot on your retina. Since each feature in the scene you’re viewing forms its own spot, your eye’s cornea and lens are forming a real image of the scene in front of you. If that image forms as intended, you see a sharp, clear rendition of the objects in front of you. But if your eye isn’t quite up to the task, the image may form either before or after your retina so that you see a blurred version of the scene.

The optical elements in your eye that are responsible for this image formation are the cornea and the lens. The cornea does most of the work of converging the light so that it focuses, while the lens provides the fine adjustment that allows that focus to occur on your retina.

If you’re farsighted, the two optical elements aren’t strong enough to form an image of nearby objects on your retina so you have trouble getting a clear view while reading. Your eye needs help, so you wear converging eyeglasses. Those eyeglasses boost the converging power of your eye itself and allow your eye to form sharp images of nearby objects on your retina.

If you’re nearsighted, the two optical elements are too strong and need to be weakened in order to form sharp images of distant objects on your retina. That’s why you wear diverging eyeglasses.

People are surprised when I tell them that they’re nearsighted or farsighted. They wonder how I know. My trick is simple: I look through their eyeglasses at distant objects. If those objects appear enlarged, the eyeglasses are converging (like magnifying glasses) and the wearer must be farsighted. If those objects appear shrunken, the eyeglasses are diverging (like the security peepholes in doors) and the wearer is nearsighted. Try it, you’ll find that it’s easy to figure out how other people see by looking through their glasses as they wear them.