The electrons that get pushed through a filament heat it up above the level where it starts to emit photons. ATA certain moment there’s an equilibrium, where the amount of electrical energy entering the filament matches the amount of photonic energy that gets emitted. This process doesn’t oscillate hence the the output is constant.

If I understand your question right, you are asking if we have pushed the electrons to a higher energy state by heating the wire up, why do they not just stay there. If the wire is hot, how can the electrons fall back down to emit light.

Humans are big, which means from our perspective, our surroundings don’t fluctuate very much. If you are in a room with a heater running, the whole room is going to be pretty warm, and all over your body is going to be more or less the same temperature.

On a small scale, this is not the case. In the wire of the light bulb, we are looking at single atoms emitting photons. On the level of a single atom, the local energy level is constantly fluctuating, the single atom is never exactly the same temperate nanosecond to nanosecond. Energy comes in, which knocks the electrons into a higher orbit, but you then have a period of time (very brief to our perspective) where there isn’t any new energy coming in. Maybe think of it like a balloon: you push in a big breath of air which inflates the balloon, but then you have to pull your mouth away and take in another breath, and during that time the air can flow back out of the balloon. So, the tungsten atoms in the light bulb filament are receiving some energy (in the form of energy leached from the electrons passing through the wire by the resistance of the wire), and they get energized, electrons get pushed to a higher orbital. Then, on the level of an individual atom, there is a brief ‘lull’ in ambient energy; there isn’t more input in that moment to keep the electron in a higher orbital. Which allows the electron to fall back down, emitting light.

This isn’t quite accurate, but hopefully it explains the idea.

**Multiple replies have given you the same incorrect answer** – that light is emitted when electrons go to a higher energy state and fall back down. That process does emit light (it is how a fluorescent lightbulb or an LED works), but that isn’t what is happening with an incandescent bulb.

An incandescent light works by sending a lot of electricity through a very small wire – the filament. Any normal material has a certain amount of electrical resistance to it, as the electrons moving through it bump around and cause things to wobble and move, which at the macro level means converting energy to heat. The engineering marvel of the lightbulb is that it lets something very small get VERY VERY hot over and over without breaking.

The light that the filament produces is **thermal radiation**. All objects are giving off thermal radiation all the time, but the amount and the spectrum of wavelengths produced depends on temperature. Room temperature stuff gives off mostly infrared, which is why we sometimes call an infrared camera a “thermal camera.” Hotter stuff, like a flame, the sun, or an incandescent lightbulb, give off mostly visible light.

So what is thermal radiation? Basically, all the molecules are wobbling around and vibrating and bumping into each other. These molecules are made of atoms and the atoms are made of subatomic particles, including electrons and protons which have their own charge. Things which have their own charge have their own electric field, and that field is constantly shifting around as the atom does. Light is essentially waves in the sum of all those electric fields put together, created by their random motion added together, just like ripples in a pool full of people thrashing around.

That is why an incandescent bulb generates ALL frequencies of light at once, since it’s caused by random motion, NOT by an electron falling from on specific energy state to another.