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! 😊💡

  • Zwuzelmaus@feddit.org
    20·
    1 day ago

    so please do correct any incorrect assumptions! I’m very eager to learn!

    It is not so much the assumptions. You need a more careful approach. Do not rush from observations to “easy” conclusions.

    the kinetic energy of the electrons

    The mechanical model does not fit here.

    If it were kinetic energy, the outcome would be very weak because of the electrons low mass. Also the electrons do not change their mechanical speed when there is electrical resistance.

    Take a good science book that explains the basics and gives you the correct formulas to do such calculations.

    • ultrafastsloth@lemmy.world
      1·
      4 hours ago

      You are right about kinetic energy having low effect. However, in microelectronics becomes an issue, called electromigration, where the material laters are so thin that this small effect of electrons on metal atoms (the electron wind force) causes erosion, basically, movement of atoms.

      Figure 2. Schematic diagram illustrating the basic principles of electromigration (EM). The flow of electrons (blue arrows) exerts an electron wind force on metal ions (M⁺), causing them to migrate toward the anode. The red arrow indicates the direction of the electric field. The brown arrows show the direction of ion migration. Dashed circles represent vacancies left behind after the migration of metal ions. From: https://www.mdpi.com/2079-9292/14/15/3151

      And the effects on the micro wires are. really something. This errosion takes time of course, but not as long and the effect rises exponentially at the end because the current density increases.

      It kinda blew my mind during my elec. eng. studies. Anyway, just wanted to donate my two cents on this matter.

    • printf("%s", name);@piefed.blahaj.zoneOPEnglish
      42·
      23 hours ago

      Had I “concluded” anything, I wouldn’t have posted in the first place.

      Reading up on the subject at my local library is on the agenda. I just have get tired of programming first. 🤣