All I know is I wanna get to know you and bring my styro, explosions n ire, and Neil friends.

@@derrekvanee4567 We all need to have dreams.

BIG HINT 🤣🤣

Wow.

Okay that's a situation where piss would pour down my ankles

If the display was neon, then as it ages, sputtering can lower the gas pressure so that it needs more voltage to ionize (ignite) a spot to get light emission. Shining a light on it adds energy to the neon atoms with the same effect as increasing the supply voltage.

_Barely_ and _barley_ are 2 different things.

The radio was a KX-155 right? Most of those King radios have a little photoresistor under the plastic next to the display which is connected to an automatic dimming circuit. As the display ages and becomes dimmer the dimming becomes non-linear and the display gets very dark /off at higher dimming levels (when the light on the photoresistor is low). By shining light on the display you illuminated the photoresistor and temporarily decreased the dimming level and the display lit up again for a while.

Thanks so much for your photo! I might have gotten the attribution wrong, but it was taken verbatim from Wikipedia, and I added a link in the description. People were asking about the "forklift driver" ;) Also, I was indeed playing too fast and loose regarding the 365nm from a 405nm laser. I just measured it, and found some 380nm, but definitely no 365. I updated the description.

So @Muonium you are Not the Gabelstaplerfahrer? Oder doch?

Powerful solid-state UV emitters (or even lasers) weren't really a thing until quite recently, so there was no practical way to make it into a consumer product back then unless you want kids at the arcade to fool around with high-voltage mercury lamps and get eye cancer from the hard UV.

​@@RealNovgorod .... do you not?

One time a coworker was trying to explain something about a particular part, and she brought up an image from Wikipedia to show me, and it was a photo I had submitted to Wikipedia lol

I was going to say that. I'm not that clear on exactly how those worked, but it immediately occurred to me that this might be related physics.

@@hfuy8005 I'm not sure either, but I think it has to do with energy states of the phosphors. It's as if they have some sort of hysteresis.

Yes! Came here to say that. Glad someone was able to say it before it got lost in comments.

He definitely provides a unique treasure of priceless informative video content, unparalleled not just on this platform but on the entire internet. He's long since impressed me to the point where I can't even measure it anymore.

hes like the golden goose of weird science ideas. dude never misses

Indeed, I also noticed this on a simple mains power block with neon indicator. The bulb would flicker in the dark and be steady when sunlight hit it. Unfortunately that bulb died a long time ago…

I recall reading that neons for logic applications had a touch of some alpha emitting radioisotope in them for that reason.

Maybe it's just more difficult to perceive the flickering when not in the dark. In the dark you would get the maximum amount of 'dynamic range' and thus easier to notice.

After reading further it seems what OP is referring to is an actual thing.

I've got an old power strip with a neon indicator... sure enough, it flickers with lights off and steady with lights on.

I think the purple photons are too feeble aren't they? 405nm is equal to 3eV per photon but argon's first ionization energy is like 15-16eV.

You're on the right track, the real explanation is that F (oxygen ion vacancy) and F+ (oxygen ion vacancy + one electron) defect centers in MgO crystals are located at 3.0 and 2.96 eV above the valence band maximum (VBM), respectively. This means that the 3.1eV 405nm laser light is exciting MgO valence electrons into the F level or maybe even exciting an electron in a F+ level into the conduction band as well and that is main reason for increasing the free carrier density in the device. The reason there is an asymmetry in the dot brightness is because the excitation of carriers in those defect levels are populated and depopulated on one side of the device for each polarization of the AC electric field. So you can imagine you have a box of balls and you raise one side and lower the other. The balls will go back and forth. This is the displacement AC current and you're not having a charge pass through the dielectric. So then the laser power is attenuated when it reaches the bottom layer of MgO because it had to travel through the first layer of MgO. Normally the high voltage AC is enough to excite these defect levels or rip them out of their position, but he is operating it in lower voltage where only the laser gives it enough energy to excite the states. The gas in the middle that becomes plasma is used as the luminescent source with a threshold limit minimum it seems. Like there needs to be enough voltage between the MgO layers to start the plasma going. The dielectric is still too insulative to pass enough charge through it. Most metals have a work function higher than 4eV and wouldn't even get excited at 365nm. The amount of 365nm light is miniscule as well. You should be able to do the same effect with regular AC EL displays with MgO too. It's all about the defect states in MgO, that is where the excited carriers start.

@@ramjetross is this the F for farbzentrum / color centers?

@@Muonium1 F (oxygen ion vacancy) and F+ (oxygen ion vacancy + one electron)

@@ramjetross That is a very convincing and knowledgeable explanation!

hey do you channel names so i can find these ppl

@@joejane9977 practical engineering is Grady's channel and Quint Builds is the other.

@@joejane9977 Would also highly recommend 'Breaking Taps', 'The Thought Emporium', 'Nile Red', 'Action BOX', and 'Codys Lab' (if you aren't already subscribed) for similar content

It is a sad twist that just serves to highlight the issue with the patent system. Protecting investment in research yes, stumbling on something no. And not being able to utilize an idea because someone patented it "just because", and not actually protecting a product they would be producing is just sad. The person who stubs his toe on something first should not be allowed to collect royalties on the dispersal of rocks.

And trousers washed... We've all been there.

At the risk of sounding like a dummy, why cant you do this? I would imagine that this essentially causes a short circuit in the outlet because the meter has little resistance, but why cant the outlet handle it? From what I understand, outlets can handle something like 1800 watts, so why would a short circuit hurt it? Wouldn't it just be limited to it's max power as if you were running a power hungry room heater? (Which I know has a lot of resistance). Basically I think my question is... why exactly cant you short circuit a plug, and why would it explode? Finally, why would it hurt your meter as long as you had it in the correct current mode?

@@Polite_Cat The voltage that comes into your house is 240v and the current that comes into your house is effectively infinite. V=IR so if you have an outlet that supplies 120v or 240v and you short it with a resistor of ~0 ohms the outlet will do its best to supply infinite current. Very few things are capable of handling effectively infinite current and they don't include multimeters or wall sockets. In theory the only thing that should happen when you short a socket is the circuit breaker popping but in reality outlets are never terminated properly and they behave more like resistors which is where the magic smoke is stored.

I noticed it was a patient monitor at 11:22, where you can see the burn-in of the most common readouts. It looks like their patients' SpO2 was consistently in the 90s.

@@simon_far 90's is pretty typical unless your having serious lung issues. I have tried holding my breath until im ready to pass out and havent ever dropped below 95%

its pretty typical to be 98 or 99%

Big Clive did make one in a video a few years ago very cool effect

you want to buy my friend

If this is activated by high energy photons, would it work for detecting radiation gamma sources? If it worked like the old fluoroscope x-ray machines, could you use it as a portable x-ray machine? Since scotch-tape being unrolled produces intense x-rays, could that flash the image of your bones in your finger overlayed on the screen?If this is activated by high energy photons, would it work for detecting radiation gamma sources? If it worked like the old fluoroscope x-ray machines, could you use it as a portable x-ray machine? Since scotch-tape being unrolled produces intense x-rays, could that flash the image of your bones in your finger overlayed on the screen?

I was wondering if it was possible PWM causing it too.

Pretty sure it's because the F and F+ defect centers in MgO crystals are located at 3.0 and 2.96 eV above the valence band maximum (VBM), respectively. This means that the 3.1eV 405nm laser light is exciting MgO valence electrons into these defect levels and that is what is increasing the amount of electron density in these defect states. The reason there is an asymmetry in the dot brightness is because the excitation of carriers in those defect levels are populated and depopulated on one side of the device for each polarization of the electric field. So imagine you have a box of balls and you raise one side and lower the other. The balls will go back and forth. This is the displacement AC current. So then the laser is attenuated when it reaches the bottom layer of MgO because it had to travel through the first layer of MgO. Normally the high voltage AC is enough to excite these defect levels, but he is operating it in lower voltage. The dielectric is still to insulative to to pass enough charge through it. Most metals have a work function usually higher than 4eV and wouldn't even get excited at 365nm. The amount of 365nm light is miniscule as well. It's all displacement current still. You can do the same process with regular AC EL displays with MgO too. It's all about the defect states in MgO, that is where the excited carriers start.

I'm guessing most of Ben's audience would've had that thought.. I'm sure he tried sweeping the laser over some laser-sensitive phosphor like a CRO screen to discount that..

Brilliant demo, still amazed the UV from these lasers and the glass barriers don't diminish the effect. Been using this to trigger a plasma in a bottle lately. If you could read back the written data from the array maybe it could make a cheaper X-ray imaging panel. :-)

And weren't the old digital-storage oscilloscopes (phosphor-based) also similar?

There any readable difference when it's brighter/darker IE voltage/resistance? That difference between acrylic & polycarbonate would be a nice way to detect plastics that's exceptionally hard to do. You try it on a solar cell? I know they emit light when you drive them in reverse and have the same sort of tech inside them. (more in the IR range though IIRC)

I was also gonna add, could the AC be made non-symmetrical to compensate for the differing brightness of which end is positive and negative? Instead of 50/50 positive and negative in reference to 0, could you do 60/40 or 40/60 and give it the additional power on that side of the waveform so it comes out even?

So many rabbit holes, so little time!

Probably terrible res

If it's possible to read, it would be revolutionary. You could turn any old plasma tv into an incredible artistic device

One way would be to stick a CCD behind the display

The resistance of the pixel changes, so that should definitely be detectable through current measurement

@@albertweber1617 like to know more details about, how to do that. I have plasma TV with me. Wanna convert it as drawing panel.

Yeah that's true, I feel the simplest explanation would be that his function generator isn't producing a perfectly symmetrical drive current, or that the panel behaves nonlinearly. However I wonder if it's bc 'freeing a hole' isn't strictly possible, i.e. it's always the electrons that actually move. So possibly you can eject electrons from the metal surface, but can't effectively eject electrons from the gas, therefore the e field has to be weak for the electrons to be ejected from the metal in the reverse polarity (but close enough to the peak to actually cause ignition) therefore shifting the reverse polarity dots to the raising edge of the reverse polarity curve.

Could it be an artefact due to interferences between the A/C frequency of the plasma and the one of the UV light?

Yes Prescott, I had considered that the laser might be pulse driven. The large and small dots could result if the waveform of its driving circuitry is asymmetric.

Checkout photomultiplier tube, not exactly a vaccum tube. But it is designed to be activated by single photon and multiply the signal

The first stages of electron accelerators (that generate the electron bunches) for x-ray lasers sometimes do this.

Video cameras with vacuum tube pickups use a photocathode in the image plane in addition to having a thermionic cathode in the electron gun.

The thing you're thinking of remind me of the LCD notepad/clipboard. It's pressure activated and erases the writing area using an electrical pulse. Costs a couple dollars. I wonder how it works. For sure there are no individual pixels there though. SONY e-book readers with a Vizplex ePaper display also have a resistive touchscreen option, those that have it come with a sketchpad application. Unfortunately the quality of implementation was garbage software wise.

I did the same thing but with an led, they were very new at the time and I didn't know you needed a resistor... connected directly to a power supply and it just exploded... bits of the plastic body all over the desk!