How diodes, LEDs and solar panels work

The electroBOOM seal of approval. That makes me happy!

Hey electro i am a big fan. You make super entertainment videos!

Now you know how a FULL BRIDGE RECTIFIER works

Hey electro boom

I like you channel can you explain transistor

Bertus van Heerden
We take this stuff in high school
It amazes me how well he explained it

Do you know why there is a resultant electric field @8:38 then?

There's an electric field because the P side has an abundance of positive charge carriers (holes) and the N side has an abundance of negative charge carriers (electrons). This excess of charge in each side causes the electric field to form between the two sides and creates a voltage potential between the two sides. That voltage is about 0.7 volts in silicon diodes, or 0.3 volts in germanium diodes. Which means electrons need at least 0.7v (in silicon) in order to cross the depletion region. Think of it like a hill where you need to give a ball enough energy to roll all the way up.

But did you finally understand it?

As someone who knows nothing about this subject I would say the same!

Does the p side of the diode ever "run out" of electrons if the photons keep "pushing' them away and through the n type side presumably eventually to a battery. Or are there just so many electrons that it doesn't matter.

​@@TwenOalley if I remember correctly you can say that the electrons from the N material that go into the P material, go out at the conductor. So there's "a new hole" for each electron that go out.
Or rather, the amount of holes won't change, they're the hops that electrons can use to move around through the material, thus they determine (along with the free electrons on the N material) the current capacity of the diode. More voltage (pressure) and the diode breaks.
From a simplistic point of view.

It's really interesting the implications of all that it's explained on the video. From this an electronics class will go through every (common) type of diode there is (though my class didn't cover solar panels).
The depletion zone will always exists, even on a conducting diode. On a conducting silicon diode it will go as high of 0.7v. Imagine having 1 ampere passing through the diode! It will act as a resistance of 0.7 ohm! And that would be 0.7 Watts of energy dissipating on such a small junction!! (now you can kind of understand why LED's need big heat sinks and old lamps don't [heat can dissipate on a bigger area, not just a small junction])
So there's tricks to control and benefit (with drawbacks) those characteristics. Diodes with smaller depletion zones but that "leaks" more current on reverse polarization, diodes that are easier to break their depletion zone on reverse and won't "break" permanently so easily so you can use that voltage as a fixed reference, etc.
And the it goes into transistors and all their types! It was a very interesting class.

@@TwenOalley yes, it's possible

@@TwenOalley if the diode is not connected electrically there will be depletion to the point where the pressure equalizes.
When it is connected as a solar electrical generator it will draw electrons out of the anode if connected to a battery directly, and pack them into the cathode thus charging the battery until the pressure again reaches equilibrium as the anode is depleted and the cathode becomes stuffed. So you could relate the intensity of the light with photon pressure balancing with an opposing electrical pressure within the battery.
I have visualized this using 2 water tanks and a centrifugal pump. One water tank is 100 feet higher than the other. Once the water level in the piping going to the higher of the 2 tanks reaches a height equivalent to the maximum head pressure rating of the pump at it's given rpm the water will stop flowing upward and the pump while still turning will be converted from a pump to a heater by virtue of a phenomenon related to fluid shear. Same thing with the solar panel, it gets to a point if it's rated maximum output voltage is less than the rated maximum voltage of the storage media, it stops charging and just creates waste heat. Part of the reason we use an inverter between the generator and the storage.

To really undertand them from an academic perspective you do indeed need a good background in quantum mechanics and math. They don't even get into them until the 2nd or 3rd year of college. But if you're just a hobbyist who's screwing aroun, yeah it doesn't take much. But don't think for a second that they're simple devices. Just look up the Schockley diode equation for a taste. Believe me, Steve didn't come close to fully explaining diodes.

​@@halonothing1 But he was told (presumably by a teacher, since he's complained to a teacher afterwards) that they'll have diodes explained to them - it's just false advertising. Nobody expects a 16 year old to understand the "academic perspective" on diodes, but the same way you can understand a piston engine without understanding the Otto cycle (like I do, I've just googled the name) or machine learning without all the calculus behind it.
And while I hate to quote people I think "If you can't explain it simply you don't understand it well enough" is appropriate - I think the teacher only knew formal definitions and couldn't (or didn't want to) explain the intuitions.

There's no replacing a persistent yet patient teacher, animation helps though

Naw mate. You've got to learn Quantum Free Electron theory to truly understand. Steve has explained an "incomplete" theory. Yeah Steve can probably explain QFET and Fermi Dirac statistics as well but just pointing out that your teacher was right about a few things

Artaxerxes
Do you have any books or links
Anything that could explain those
I’m currently learning physics on my own
Any sources would be helpful for the topics that you have mentioned

I second this!!

No,that would be useful

seconding

Yep! Agreed! I use transistors and diodes but this is the first time someone has managed to explain WHY they work, would love to see an explanation for the transistors but I think I can now guess :)

That would be great 👍🏻

Brassica more like bra stuffing Jessica

Same

@@AndrewStinton Solidarity, friend 😑

Erixon You’re right, this guy is an amazing teacher. But your arithmetic is scary: Do you really watch a million videos for every comment you write? I’m retired, but even I don’t have that kind of free time.

I wouldn't trust someone who is so inexperienced and a novice at commenting, I'd rather hear from someone who is a professional commenting expert, like Justin Y.

Maybe he isn't gonna say that on a video for his entire life

@@smartypants1588 smarty pants trying to be a smart ass

Exactly I couldn't have said it better...this video makes me haye all my teachers who pretended to be one and just read off everything from the text book...

@@deadheadliving yeah I'm always jealous of the people who had that one teacher that made a difference in their life. The only thing I can remember about my public school teachers is there is one of them that ate paste.

Yeah but it's not always the case😂😂🤭

I respect good teachers

Your chemistry lecturer maybe wasn't aware that he is atoms. :P

B R U H

The smooth brains have lost another one :(

now that your brain is getting better you can stop using bruh,,, also, the value of your car audio should never exceed the blue book value of the car, and put a real muffler back on it, and take off the stupid 3' tall wing, lol

and please pull up those pants, we don't need to see your underwear

@@jakeqwaninne8502 I'm 52 Jake, I was using Bruh just to be silly. Love how you judge someone on the use of a word tho, thats so cool of you

Same! University lecturers often do not have a teaching qualification, only expertise in their field. BOTH are required.

A lot of university professors are obsessed with being extremely formal all the time, and that alone makes it harder to follow them.
One textbook that says "screw that" to all of that is "Introduction To Classical Mechanics" by David Morin.
That book is written almost like a kindergarten book, with very casual language and even with limericks thrown in here and there just to ease the mood a bit, and it is _only just_ formal enough to still be acceptable teaching material with correct definitions and proofs etc.
And you know what?
_That works perfectly fine!_
So that book proves once and for all that all those irritating formalities are completely unnecessary - _it is possible_ to teach science courses without a ton of formalities and stiff language everywhere.

@@Peter_1986 It might make it harder to follow but with these kind of subjects there are asterisks attached to everything. The formality is kind of required to avoid confusion should you go further into depth.

@@someonespotatohmm9513 exactly,you are supposed to do further study/research to understand stuff...

@@ppsarrakis Yes let me teach you all these things.
2 weeks later when you need to do something with what was thought: You remember what you needed to know 2 weeks ago? well forget about that it was wrong, good luck figuring out what was wrong (as no asterisks where given) and looking up what is actually going on.
I see nothing wrong with this... (This stuff still happens somewhat with asterisks but at least there is a starting point and you have some idea about what is going on)

Hol' up

This is hilarious and I don't know what the term for what you just did is!
What is it!?!

@@Ratchet4647 I don't know but it reminds me of the "Self-Demonstrating Article" article on TV Tropes.

So does your chair.

Only after you open the box with schriedingers cat in it, only then you know if the cat loves anthropmorphize. Wjil in the box it both likes and dislikes it at the same time...

+

@@sillyshitt

Paradox _tenses,_ much? 👀

Ikr

I remember when I was in school (a long time ago now!) and I always seemed to gravitate towards learning from people who were passionate about the subject they were teaching. People who would explain not only what was going on but, usually from their own perspective, why it was interesting. I may not have always agreed that it was interesting but I found their passion for the lesson made me remember the information presented to me. For example, I had a maths teacher who would tell us "just do the sum!" and I didn't pick it up. When I moved class because she was a shit teacher and we did NOT like each other, I was taught the same lesson by a different teacher who explained it, how it could be used and gave a real life example and seemed excited to be explaining it. I learned how to deal with differential equations.
If you find your subject interesting/exciting, use that enthusiasm to teach the kids mate. It goes a long way! And keep up the good work. Teachers need more recognition!

have a read: www.sciencedirect.com/science/article/pii/S0927024805002345
Or: Depends on the material your "solar diode" is made of.

@@zn4rf this is not free?

The materials I think, that’s probably what the entire industry behind it is about. What materials make efficient and cheap enough mass produced diodes.

Material has a lot to do with it. A silicon diode drops about 0.6 to 0.7v, where a germanium will drop 0.25 to 0.3v or there's a special kind of diode called a schottkey diode where the junction is formed between silicon and a metal which drops as little as 0.2v. This is important, because Ohm's law states that power=voltage x current. So if you have 1 amp of current through a diode, the silicon diode will draw 0.7 watts of power (0.7v x 1A) where te schottkey diode will draw 0.2 watts. This power is just dissipated as heat, so any power drawn by a diode is wasted power. So the less power consumed, the more efficient it is. I hope that helps.

There is also quantum efficiency in LEDs, Photodetectors and Solar Cells which is the fraction of photons to electron-hole pairs generated or LEDs/LASERs the fraction of pair recombinations that actually result in emitted photons.
This efficiency does have to do with resistive losses and absorption by the material in areas other than the depletion region. Also Reflection at the surface.

Another factor for lighting is simply many bandgaps are wavelengths (or for our eyes, colors) that we don't directly want, so they will have a phosphor coating to absorb and re-emit at a more pleasant color. Obviously this eats into efficiency.. if I remember correctly, a green LED was sort of elusive so many white lights just had to use blue light with a coating... Although don't quote me on that haha

Tests.

This is useful feedback thank you.

Desire to puke rising and only half way through. Excellent video though. Would have loved having this when I was in college. Makes things much easier to understand.

Agreed!

Omg. I was just looking in the comments because I was feeling weird from the shaky videos. I felt dizzy. Didn't know it could be slight vertigo.

This isn't really a correction, just pointing out a potential incorrect statement.

This video is simplified, semiconductor manufacturing is another story.

It *can* be made by just pushing p and n type materials together, even though often industrially it is just two halves of the same piece of material doped differently.

Unless its teflon

@@wierdalien1 Well, yes and no. There's some incredibly stable organic fluorine compunds, like tetrafuoromethane, or teflon (PTFE) that you mentioned. That would be fluorine in its 'happy' state. And even those compounds usually fuck up the environment and/or people either during their creation, their disposal, or when handled incorrectly.
As for 'angry' fluorine... take a look at chlorine trifluoride. Or maybe not. Running away would be smarter. Or better yet: Be somewhere else than that stuff in the first place.

​I love the way you anthropomorphize atoms, NaHCO3

@@nahco3994 well yeah creation of PTFE requires straight flourine

What do you mean, floorine is what the floor is made of, what else am i supposed to walk on?

A introduction can either be too simple or too detailed. I think this video makes a good first introduction to diodes.
And if someone wants some more exact details, then they should look for such additional info. Such as solar panels having multiple layers of semiconductors, to account for different wavelengths.

@@suddeneevee9441 Thanks for your post. I've no problem with any of that, but IMO the concept of selective doping vs. joining separate pieces of doped silicon together doesn't represent a huge leap in the complexity of the concept or its presentation. It would certainly take fewer words than this comment has. 😉

It has to do with the way diodes break down. In any diode, you still get a very weak reverse current even if the diode is "blocking" because some of the charges are able to cross the depletion zone. Once you approach the breakdown voltage, some of those moving electrons have enough energy to knock electrons that wouldn't normally be free-flowing out of the covalent bonds, and the reverse current sharply rises. This is known as "Impact Ionization" or the "Avalanche Effect". Note that this, in itself, isn't actually damaging to the diode - what damages the diode is the massive current flow and the heat that results from it.
Now, a Zener diode has essentially the same construction as a regular diode, but the material is more "heavily" doped. This means that there are more charges in the same volume, and as a result the depletion zone is much thinner. The voltage across it is still the same, though, so the electric field across the depletion zone is much stronger. When you connect a diode in reverse, the electric field across the depletion zone gets stronger, and in the case of a zener diode, strong enough to rip electrons out of the covalent bonds and allow a high current to flow. This is known as the Zener Effect.
According to Wikipedia, only zener diodes up to 5.6V actually use this effect, though. Zener diodes for higher voltages supposedly rely simply on the avalanche effect - kind of makes sense, because at that point you're essentially just manufacturing a normal diode. The breakdown voltage is engineered through how heavily doped the material is.
It gets a little more interesting, though. Impact ionization is just a matter of raw energy, but the zener effect is actually a quantum tunneling effect. The upshot of that is that low-voltage zener diodes supposedly generate a lot less heat than zener diodes that rely on the avalanche effect.

All are diodes, but the first "diodes" you mention are usually called "signal diodes" because of their application.

Actually, rectifying diode or maybe PN junction diode would be better to distinguish regular diodes from the rest. But signal diode is just fine for low power ones which are (obviously) meant for signals. I'm pretty sure a solar cell also uses a PN junction, but the reverse breakdown voltage is so small and the reverse recovery time so long that they would make a terrible rectifier. Zener diodes and avalanche diodes also don't rectify very well either for the same reason.
So it seems rectification isn't the sole defining feature of a diode. But at the same time, not all diodes use PN junctions either. Like PIN diodes, which have undoped, or intrinsic semiconductor between P type on one side and N type on the other.
Or schottky diodes, which only have a P or N type layer on a metal layer, as in the famous cat's whisker or point contact diode used in foxhole radios.
So in terms of what exactly defines a diode, I have no clue. but I aim to find out now that I've realized this. Hope you guys will, too. Cheers.

Fries, Chips and Mashed Potatoes

Why has no-one commented on this, even just in banal admiration of the sentiment? We need naturally solar-powered AMOLED phones!

I don't think it's optimized for that. The charging rate would be slower than depletion rate.
But it would be cool if it was optimized for that :)

You mean Ions? Cations?

Yeah, they're both Ali A's brothers

@@JamecBond And the distance between the top of the LEDs and the rim of the beaker is the energy gap. Jiggle it around (thermal energy) and some will leap out! :)