The high resistance piece of wire in incandescent light bulbs glows as a result of electrons incoming through a low resistance material being squeezed through (bombard electrons that don’t want to be moved in) the high resistance material with a certain pressure (voltage). We are using the high resistance material to usurp (convert into heat and then into light) the kinetic energy of the electrons in the low resistance material (commonly copper wire).
We do the same thing with electrical heating elements and microphones.
Are we also doing this in electrical appliances from which we don’t expect a certain “end product” (heat, light, sound)? For instance, computers. When we were still using actual physical relays to build logic gates, I can imaging electron flow being converted into the energy (eletrco magnetism?) required to actuate/move the switch inside the relay. But what about today’s transistors? The processing units inside CPUs and GPUs heat up, but that’s a side effect of something I don’t understand. We are not trying to reap that heat. We are after manipulating groups transistors into expressing boolean logic by either giving them a voltage or not.
I know very little of electricity, so please do correct any incorrect assumptions! I’m very eager to learn! 😊💡
Radiowaves are a color of light that we can’t see. Technically “light” typically only refers to visible colors, and we call everything else “electromagnetic radiation”. Radio waves, microwaves, and infrared light are past the red end of the rainbow, while ultraviolet, x-rays, and gamma rays are past the violet end of the rainbow. All of these are self-propagating ripples in electromagnetic fields.
It’s very difficult to actually destroy an electron. When I said the electrons are “depleted” in a transistor I meant they are pushed somewhere else. Electrons can be pushed and pulled by electromagnetic fields, so in a transistor one current makes a field that pushes electrons out of the region where they would need to be for the other current to use them.
In all cases it’s the electromagnetic fields that actually do the work.
If you want to know about electrons actually being destroyed, an electron will annihilate with a positron (antimatter electron) releasing some gamma rays. There are some medical applications for radioactive material that produces positrons which annihilate to produce gamma rays in this way, and then they can detect the gamma rays.
Thanks for all the clarifications! It’s mindboggling and fascinating how we found out about all this, came up with concepts and pointers - language - to express and describe it all.
For the fundamental concepts of electromagnetism, see ‘Maxwell’s Equations’. Personally, I prefer looking at the differential equation versions to understand the interplay between electro- and -magnetism and how that relates to light/electricity/so many things