It was almost impossible to make the blue LED [video]

It's complicated.

For 1 employee which disobeyed orders and saved the company you'll have 99 which disobeyed orders and don't produce anything useful or even made harm.

This is called the Halo effect.

They didn't sack him, he quit for better pay.

In Japan companies rarely sack employees and employees rarely quit. People are expected to stay with the same company basically their whole life. That's why he didn't get fired for disobeying orders. Firing someone in Japan is somewhat socially taboo (just like quitting) and therefore rare.

In Japan, companies are considered to be like "family". It would be kind of a joke here in the USA, but in Japan there is a lot of loyalty in both directions.

Part of the reason they sued him is probably the butthurt of him quitting. Quitting, even for better pay, is kind of like a big "fuck you" in Japan.

Totally. I actually went to check mouser to see if they had nichia brand stuff - a few odds and ends but they're not even listed on the manufacturer list for LEDs.

Will watch out for them and avoid whenever possible from now on.

I agree with you. It says the original CEO was a researcher himself and that's why he understood the risks funded the request. Things changed after his son-in-law took control as CEO. It doesn't mention if the son-n-law had any background in the industry or semiconductor research, or was just appointed CEO just because he was the son-in-law. I think that's where the company went wrong.

The Nichia 519A is a one of the favourite LEDs in the enthusiast flashlight world.

It's a high CRI quite bright LED, and I have to shamefully admit that I specifically specced a light in the past with this LED.

Before I knew about this, that is.

Example write-up to see what flashlight nerds talk about: https://budgetlightforum.com/t/nichia-519a/64360/43

This makes more sense having learned more about Japanese business culture and the concept of salarymen.

Like the other person said, nichia makes good LEDs. They make a UV free LED. https://led-ld.nichia.co.jp/en/product/lighting_optisolis.ht...

I can, though indirectly.

Odds are good I've bought hundreds of consumer goods with Nichia LEDs in it without knowing, and I'll probably buy hundreds more.

(Not that I'm endorsing not caring, just pointing out how frustratingly hard it is to avoid giving money to companies like this.)

Blue LEDs that are on to let you know something has power is abominable, but that isn't the fault of the blue LED. What is abominable is the use of the "cooler" blueish white light being used at night indoors. That should be considered a crime against humanity.

I wasn't a big fan of the excessive blue LEDs that appeared everywhere after they were invented, either. Though it was understandable enthusiasm for something new by product developers, after decades of having only red-green combinations.

But blue LEDs are what make white LEDs work, and those have revolutionised ordinary lighting in a big way. The linked video goes into this at the end.

Blue LEDs (or white LEDs, or blue OLEDs) are also used in modern, high quality computer and phone displays.

????? Blue LEDs made white LEDs & LED displays possible. And blue light being bad for your circadian rhythm is just as true for an LCD display as it is an LED display.

Having blue allowed creating white, and anycolor (RGB) LEDs, so I would not dismiss them just because you don't like the blue color

Blue leds also gave birth to purple leds, which for some reason every condo building has multiple units lit up like vampire dens.

Green SMD LEDs are just as bad.

You could, you know, tape over them or something, about 5 mins of work.

Seems like an extreme stance for a easily solvable problem.

The color blue is responsible for a lot of misery.

Maybe try an eyemask? I will admit the feeling takes a little bit getting used to but I get way better sleep with it than without.

I wonder if there is a part that could replace signaling LEDs without emitting their own light. I think transflective LCD could work like that. Make it small, round and with two contacts like a diode.

no, we've put it on your headphones, your electric blanket, your everything. the blue led must be seen.

I liked it, though it bugs me a little when people equate infrared and heat. Infrared is light. Light can heat things, and hot things can glow, but "infrared is heat" isn't exactly right.

Yeah, all I can say is that is tracked my undergraduate semiconductor theory classes pretty well. More confirmation needed.

Bachelor's in engineering physics (condensed matter experimental)/EE specializing in semiconductors here. The explanation starting at 4:00 is very accurate.

When he talks about the electrons "feeling" the neighboring atoms, he's talking specifically about a result that follows from the materials being crystalline, that is, having regular ordered structure. The regular structure gives rise to a periodic potential. You plug that periodic potential into the Schrodinger equation and apply continuity conditions and translational symmetry to the wavefunction. Computing the solutions to the Schrodinger equation with those conditions reveals that there are allowed and disallowed energy levels, and also reveals the relationship between energy and momentum in the crystal lattice. You can step through this by reading the wikipedia page on the Kronig-Penney Model. This depends on the periodicity, which obviously can change depending on direction in a crystal.

His explanation, and the result that "the" band gap is a single number, isn't dishonest because when we grow semiconductor devices, we grow them such that the crystal is oriented such that current flows in the desired direction, so that simple result holds true.

Even his portrayal of the bands leaning down as potential/voltage is applied mirrors how potential change is shown in diagrams of semiconductor devices, see Streetman and Banerjee - Solid State Electronic Devices.

My 5 and 7 year old watched the whole thing with me and had lots of follow up questions for me.

The explanation is really well done, it captures the essence of the Pauli exclusion principle without delving too deeply into the weeds. In my opinion the best part of the video is the explanation of the "hole" quasiparticle at 6:10 (I learned this as a pseudo-particle but will defer to Wikipedia [1]).

While a great introduction to semiconductor behavior this does gloss over a very important detail namely direct vs indirect semicondoctors as some others have mentioned. In the video the detail that's glossed over relates to the nature of crystals, namely that they're highly ordered repeating structures but that they don't look the same when viewed from every direction. This means that there isn't a single band-gap but multiple ones depending on the direction of the crystal you're contemplating.

At this point you may reasonably ask why the direction matters and now we unfortunately get deep into the weeds with quantum mechanics again. When a single photon is absorbed in the semiconductor system both momentum and energy must be conserved. The momentum of the photon for something like the Silicon bandgap is quite small (something like the equivalent of an electron traveling at 1500m/s) while the momentum of room-temperature conduction electrons is substantially faster [2] so as a very slight simplification transitions due to the absorption of photons are not accompanied by a change in momentum and so we only care about the band structure (and the accompanying free carriers) associated with a particular crystal direction.

In particular in Silicon you have what's called an indirect bandgap, namely the minimum energy conduction band electrons have a different momentum from the valence band holes ([3]) and as a consequence while you can _absorb_ a photon in order to make a detector you cannot make it efficiently _emit_ a photon as an LED should (something the video got wrong).

None of this matters for the heart of the video, which focuses blue LEDs in the GaN materials system which is definitely a direct bandgap material, however if someone does manage to create a manufacturable light emitter in pure Silicon expect an absolute revolution with regards to optical computing and photonics. (Not for lack of trying, this has been the holy grail for at least 20 years, possibly longer)

[1] https://en.wikipedia.org/wiki/Quasiparticle [2] https://www.chu.berkeley.edu/wp-content/uploads/2020/01/Chen... [3] https://www.iue.tuwien.ac.at/phd/wessner/node31.html

I agree. Setting how LEDs work aside, I never really got how semiconductors worked, despite reading about it and talking with experts for years, until this video.

I mean, I could explain how they worked in the same ways that they were explained to me, but I couldn't connect those explanations to a true physical understanding.

But thanks to this, I finally actually understand.

Also, the LED story was fascinating.

What's your point? That statement has nothing to do with the problem at hand.

Blaming literally anything wrong on "capitalism" is peak intellectual laziness. Especially to use a canned definition that no one would agree to except those that would confirm your priors.

Do these problems not exist under feudalism? Mercantilism? Communism? Did soviet inventors fair any better?

You're better off calling a spade a spade. Weird reductionist absolutes about society don't make any of us any smarter and only steer discussions into unhelpful directions.

Please don't take HN threads on generic ideological tangents. They're tedious and repetitive, and therefore boring. Plus then they turn nasty.

https://hn.algolia.com/?dateRange=all&page=0&prefix=true&sor...

https://news.ycombinator.com/newsguidelines.html

Edit: can you please not use HN primarily for ideological battle? We have to ban accounts that do that because it destroys what this site is supposed to be for. past explanations: https://hn.algolia.com/?sort=byDate&dateRange=all&type=comme....

Could you please stop using HN for ideological battle? Your account has been doing this a lot lately, and when an account is primarily doing that, this is a line at which we ban the account. Past explanations: https://hn.algolia.com/?sort=byDate&dateRange=all&type=comme...

We detached this subthread from https://news.ycombinator.com/item?id=39314755.

It’s always been like this.

Professions that leverage passion pay peanuts.

The person created probably close to trillions of value to humanity (his LEDs spawned multiple new industries), yet he was compensated less than what I make with web development.

While decrying unfairness towards a single researcher, you seem to ignore the contribution of who knows how many people comprising "multiple new industries". I mean, the people working in those industries also contributed to those trillions, no?

It definitely seems unfair to Nakamura. Just pointing out it's really hard to be fair to everyone, as your comment inadvertently proves. At least he got a Nobel prize, which means both recognition and money.

Wow, I had the completely opposite interpretation. The only reason this thing got created was because one rich person bet $3 million dollars on this researcher. There would have been zero chance of this research ever getting funded outside of capitalism.

Without that corporation behind him there's no way he would have been able to go to America for a year, buy a brand new deposition machine and then spend more years working on it.

LED lighting wouldn't exist if not for blue LEDs. And neither would much of modern display technology. The importance of this discovery was not because we could make shiny blue light with it.

You never had a problem with green?

Do you like OLED displays?

You're comparing a whole billion people to someone who went on to earn a Nobel, it's a little unfair. There's plenty of people in the West (and East, and South and North) with massive, even unhealthy grit and determination, and plenty of people in Japan that just conform to the standard work culture of the country.

The puzzling thing is how he was able to just keep ignoring orders from management to stop working on the pet project. Clearly this required quite some resources to continue and he didn't get fired. I don't know if I could get away with this at a Faang-type job.

Very refreshing when contrasted with western mentality, where people can't wait to get promoted fast enough.

The guy arm-wrestled the laws of physics to create something everyone including his own bosses said was impossible, and for his labors he got raised to $60k/yr (yeah I know it’s more now, but not like 10x more). I’d say this is more of a cautionary tale for ambitious inventors to demand their worth from their employers, as opposed to a fable about good things happening to people who keep their heads down and just work.

Are you sure they were RGB triplets and not white LEDs? Either way, is fun to imagine continuing this - grouping three of these filtered LED lights to make a new white light source, which you can then again filter with translucent plastic, etc!

The blue is nicer if you do that. Technology Connections has made 3 videos over the last 5 years mostly centering around how he hates the blue led lights used in holiday lights. I think I've only seen the 2 yr old one, but now that I have I can't unsee it. The blue is just too blue. If you see a set that is all blue instead of multi-color it's unbearable. It's just too blue. White light in blue plastic is where it's at.

https://youtu.be/PBFPJ3_6ZWs?si=sTeRrqQ5umHsNCgz https://youtu.be/cQgcTkXacAc?si=CDj0G9Sh7S-wbLjN https://youtu.be/va1rzP2xIx4?si=cAp65hnmwtkrXgDc

I think it was narcissism. Nakamura ignored direct orders to desist for years, and wound up proving that those orders were massive strategic blunders. So insubordination combined with making his superior look a fool. (On the other hand it's pretty clear we're only getting Nakamura's side of the story.)

They sell LED dimming (and blackout) stickers on Amazon, and those things have been a lifesaver for me. My new USB-C charging block is brighter than the sun and the LED is functionally useless, so it's been masked with the blackout version of the stickers, but my Dyson fan which has a blue power LED (which turns to red when it's on heat mode) and BRIGHT WHITE LED temperature readout in heat mode has gotten the dimming treatment. Nice because you can still see the light, but 80% less bright, so I can sleep at night.

Yeah, that first generation was quite a novelty and really bright.

I got a couple blue ones but never went back for more, stuck with green and red when I built something.

The blue came in handy for a musician who was legally blind though.

This was before commercial pedals had any blue, so it did get some attention.

Blue LEDs are an amazing and badly needed advance -- but you're right, the abuse of blue LEDs has been, and continues to be, really awful.

a good leader need to be humble enough to spot when they are wrong and correct course. This guy sounds like he had control issues, and kept a grudge. very childish behavior.

I feel like I remember he complained that Japan would likely fall behind by their best and brightest going outside Japan knowing that inside they would not be compensated.

My search-fu is failing though. I did find this interview

https://www.jsap.or.jp/jsapi/Pdf/Number02/Interview.pdf

I thought all LEDs are uv-free, except those specifically designed for UV?

https://www.lcsc.com/products/Light-Emitting-Diodes-LED_528....

Pink LEDs need a custom phosphor so they may not be available in some sizes. They are also not in high demand, so not a lot of different parts are made.

I still remember the blue power LED on my Toshiba laptop fading on and off in a pattern that was not quite the patented Apple "breathing" pattern, but close enough to suggest it.

Yes - there was Time that every consumer device insisted on using extremely bright blue LEDs for “power on” status. Even mundane things like DVRs or TVs. It became so annoying that various forms of tape were use to cover them.

I’m glad those days are over.

Kudos for mentioning Back to the Future. When I was 8/10 yo, I could recite all the lines from the first movie up to 15 min or something. I really, really loved it.

Selenium is much more toxic than gallium, so even if it could be tweaked to work, it's a very hazardous chemical to produce or recycle. I'd expect that to be the main reason nobody bothers with zinc selenide anymore.

I totally agree - save blue LEDs for non-domestic cases - they really suck at night - mess up the circadian rhythm.

That's what I've seen, engineers working 50-60 hour weeks like it's gaming company or a faang. Except it's Hitachi. Bonus a lot of these guys are fluent in English. In the bay area they could make double for half the hours.

Veritasium traffic is far bigger than HN.

Statistically speaking, more of those having this natural level of talent for experimentation & discovery will not be those having a PhD.

maybe thousands, of others also worked hard, and bet years of their lives, and… failed.

For most of them it was not the lab where they were so hard at work.

Some of them bound to be conducting their financial survival activities working in places like fast-food companies, and worse in positions where they aren't allowed to even fix things like broken milkshake machines.

Far outnumbering the highly significant percentage of PhD's who are not gifted experimentalists but they are the ones hogging their share of equipment and facilities.

So a huge amount of expensive facilities don't do any good, and the vast majority of those ultimately capable of getting something out of it end up getting nothing done. Of the sort.

Not just the blue LED.

This is what made the white LED possible.

And as can be seen, not only incandescent but also LED lighting was only made possible when it was by truly Edisonian efforts.

Anytime there is an opportunity to score inexpensive, relevant gear, they do it.

Up into the 1980's things were done a bit differently than they are now in industrial research when it comes to equipment.

For energy, well-funded places like Exxon and Shell would store and accumulate used equipment in surplus warehouses when they recommissioned laboratories or replaced individual gear with the latest & greatest. There it would age for 5 to 10 years on average before being tagged for discard.

The material was traditionally being held as a resource as in previous decades, when it was expected that principal investigators would look first in the vast storehouse for useful items before requisitioning & purchasing new equipment for their labs. But nobody was doing that any more, energy had skyrocketed in price and oil companies had plenty of money so they had only been buying new equipment for years.

These were big warehouses, but eventually they would fill up and stay full, and they needed to make room for more on a regular basis so things were auctioned off.

Cashthedayofthesaleasiswhereisnowarrantiesofany kind.

I ended up with a very small (carefully selected) fraction of what was passing through those warehouses, and it was still a nice multiple of the tonnage that any one PhD had at their disposal during an average career. A lot of them don't want to touch the equipment anyway, they make the interns do it. So it's not often the most scientifically advanced one in the lab leveraging their hands-on experience, and conversely seldom the most capable hands-on operator having their abilities leveraged most scientifically.

I collaborated with some of their people who would visit my lab at the time, plus non-research customers and there was nothing to be ashamed of using their second-hand equipment which still had inventory stickers from the original owners. I was constantly validating equal or superior performance to their own in-house work.

They would never think of using their own surplus equipment or even going down to the warehouse to see how much overwhelming tonnage there actually was.

It just wasn't done.