Mostly because that’s the part that’s most useful and it’s the part that’s most abundant. But there are some other problems sensing light outside of our visible spectrum.

Our sun peaks its output in the yellow-green part of the spectrum and as you can imagine that’s the part we’re most sensitive to. There’s just a lot of it, so that’s the most useful part to be looking for. A lot of UV gets absorbed and blocked by the atmosphere, and of course there’s almost no UV at night.

As well, a lot of wavelengths like radio and higher UV tend to just go straight through matter. That might *sound* useful but if you’re trying to look at *this thing* and the light is going through it, you’re not going to see it. Or you’re going to see multiple overlapping shadows and you’d have to figure out which of them on top.

Regardless, visible light is also kind of unique in how it interacts with light. Photons give electrons energy, right? In the visible spectrum, the energy is enough to move electrons up into higher “orbits” around their atomic nuclei, but only temporarily, which is good. That shift in electron orbit will change the shape of the molecule that atom is in, which is how we detect light. The photon energizes an electron inside of a protein, and that protein changes its shape. That interacts with other proteins, which causes the nerve to fire.

Above visible, the energy can knock the electron off entirely. That’s bad, because it breaks your detector protein. That means every time you detect a UV photon, you’ll probably have to rebuild your detector. And also, if that photon hits something *other* than your detector, it’ll break that too. So it can break your other detectors, other parts of cell in your eyes, and generally mess up everything. It’s much safer to block all of it out with proteins deliberately built to safely absorb and block that dangerous UV.

Below visible light, there’s not quite enough energy to move the electrons up. Instead, they kind of wiggle around like a duck bobbing on a wave. That’s harder to detect, and when you do, it takes a lot of detectors working together. Between that and the larger wavelengths, the vision you get is a lot less precise. That’s why things that detect infrared, like pit vipers, use it to sense heat in a more general “it’s over there” kind of way instead of a precise, “I can see this thing right here” way.