I noticed the longer term at CES 2023, and I wasn’t even planning on going. When Nanosys, an organization whose is in thousands and thousands of TVs, provided to indicate me a top-secret prototype of a next-generation show, I booked a resort instantly.
What received me so excited? Electroluminescent quantum dots. It is the next-generation tech that can be a part of and presumablyfor telephones and TVs. It guarantees improved image high quality, vitality financial savings and manufacturing effectivity. A less complicated construction makes these shows theoretically really easy to provide, they may usher in a sci-fi world of cheap screens on all the pieces from eyeglasses to windscreens and home windows.
The prototype I saw at CES wasn’t simple, however. Inside the Nanosys suite at the Westgate hotel, a short walk from the convention center, tables against the walls showed different TVs and monitors featuring quantum dots. And there on one table, farthest from the door, was the 6-inch prototype I had come to see. A maze of wires connected it to multi-tiered circuit boards. It was impossibly flat, like a vibrantly glowing piece of paper. A gallery of colorful nature images cycled through on screen, the de-facto standard content for pre-production display demos.
It felt like I was staring at something from the future, because, basically, I was. It’s so cutting-edge, Nanosys said I could only show a blurred image and couldn’t take any video. They told me their as-yet-unnamed manufacturing partner is going to be talking more about the technology in a few months, however, so hopefully we’ll learn more soon. In the meantime, here’s what I can tell you.
The QD past and present
Let me back up a moment. Quantum dots are tiny particles that when supplied with energy emit specific wavelengths of light. Different size quantum dots emit different wavelengths. Or to put it another way, some dots emit red light, others green, and others still, blue., but for display tech, . They’re also extraordinarily efficient, almost perfectly emitting the same amount of energy absorbed.
For the last few years, quantum dots have been used by TV manufacturers to boost the brightness and color of LCD TVs. The “Q” instands for “quantum.” Originally only found in high-end TVs, quantum dots now found in mid- and lower-end TVs from brands including Samsung, TCL, Hisense, LG and Vizio. They enable , higher and more.
More recently, Samsung. Their (and partner Sony’s) QD-OLED TVs have some of the best image quality of any TV ever.
Until now, quantum dots were always a supporting player in another technology’s game. A futuristic booster for older tech, elevating that tech’s performance. QDs weren’t a character on their own. That is no longer the case.
Direct-view quantum dots
The quantum dots used in display tech up to this point are what’s called “photoluminescent.” They absorb light, then emit light. With LED LCD TVs, this usually meant LEDs emitting blue light. This blue light would be the blue light you’d see on the TV, but it was also used to cause red and green quantum dots to emit their own colored light. So what you’d see on screen is blue light from the LEDs, and red and green light from the quantum dots, all combining to help create an image. There are a variety of ways to implement this process, but that’s the basic idea.
The prototype I saw was completely different. No traditional LEDs and no OLED. Instead of using light to excite quantum dots into emitting light, it uses electricity. Nothing but quantum dots. Electroluminescent, aka direct-view, quantum dots. This is huge.
Or at least, has the potential to be huge. Theoretically, this will mean thinner, more energy-efficient displays. It means displays that can be easier, as in cheaper, to manufacture. That could mean even less expensive, more efficient, bigger-screen TVs. The potential in picture quality is at least as good as QD-OLED, if not better. The tech is scalable from tiny, lightweight, high-brightness displays for next-generation VR headsets, to highly efficient phone screens, to high-performance flat-screen TVs.
Nanosys calls this direct-view, electroluminescent quantum dot tech “nanoLED” which, for the record, I don’t like. The TV marketplace is filled with “LED” things and I think it’s a bit of a stretch to ask the average person to understand “nano” is different from “” and “ .” But hey, if I was good at marketing, I’d be a lot better paid.
The sci-fi future
The potential with TVs and phone screens is exciting, but that’s not where the potential of electroluminescent QD ends. Having what amounts to a simpler display structure, you can incorporate QD-based displays in a wider variety of situations. Or more specifically, on a wider variety of surfaces. Essentially, you can print an entire QD display onto a surface without the heat required by other “printable” tech.
What does this mean? Just about any flat or curved surface could be a screen. This has long been the promise of a variety of technologies, not to mention countless sci-fi shows and movies, but electroluminescent QD has the potential to actually make it happen.
For instance, you could incorporate a screen onto the windshield of a car for a more elaborate, high-resolution, easy-to-see, heads-up display. Speed and navigation directions for sure, but how about augmented reality for safer nighttime driving with QD-display-enhanced lane markers and street signs? Or imagine a windscreen that can show you, without taking your eyes off the road, where other cars are around you. These types of QD-displays could have a light transmission of 95%, meaning they’d look pretty much exactly like normal glass when off.
Since I first got eyeglasses, I dreamed about having a screen built in that could show me info like in a video game. AR glasses have been a thing, but they’re bulky, low resolution and, to be perfectly honest, lame. A QD display could be printed on the lenses themselves, requiring less elaborate electronics in the frames. They could look just like regular eyeglasses, but show incoming message info, a video call, maps, or a movie. It’s all very cyberpunk.
Pretty much any surface could work like this. I think an obvious early use, despite how annoying it could be, would be bus or subway windows. These will initially be pitched by cities as a way to show people important info, but inevitably they’ll be used for advertising. That’s certainly not a knock against the tech, just how things work in the world.
Beyond the quantum realm
The history of CES is littered with advanced prototypes that never came to market, relegated to history and the minds of bald, bespectacled tech journalists. Nanosys has a solid history, and works with the biggest names in the manufacturing world. This is what they’ve been working towards for years. It was always at the edge of the timeline they’d share every year. When I first met with them several years ago, the first displays with quantum dots were about to hit the market. Now they’re everywhere. A few years after that, they talked about adding QD to OLED. Now those are here. QD on its own, direct-view electroluminescent QD, was always their goal. And now it’s here.
Well, sort of. It’s a prototype. Even Nanosys admits direct-view quantum dot displays are still several years away from mass production.
The cost of early production will determine what size we’ll see initially. Phones and VR headsets first, then TVs later? Could be. TV manufacturing facilities are expensive to build, and companies aren’t going to want to convert or close older factories before getting a full return on investment. So it’s likely we’ll still have legacy LCDs with quantum dots alongside QD-OLED alongside direct-view QD on store shelves for the near future.
Beyond that, who knows? Some new tech will certainly come along that will be even better. But 5-10 years from now we’ll almost certainly have options for QD displays in our phones, probably in our living rooms, and possibly on our windshields and windows.
Yep, seeing that was definitely worth the visit to CES.
As well as covering TV and other display tech, Geoff does photo tours of cool museums and locations around the world, including nuclear submarines, massive aircraft carriers, medieval castles, epic 10,000-mile road trips and more. Check out Tech Treks for all his tours and adventures.