Three scientists have jointly earned the Nobel Prize in physics for their work on blue LEDs, or light-emitting diodes. Why blue in particular? Well, blue was the last — and most difficult — advance required to create white LED light. And with white LED light, companies are able to create smartphone and computer screens, as well as light bulbs that last longer and use less electricity than any bulb invented before. The invention of blue led revolutionized the digital world of ours which we are experiencing today.
The 2014 Nobel Prize for physics has been awarded to a trio of scientists in Japan and the US for the invention of blue light emitting diodes (LEDs). Professors Isamu Akasaki, Hiroshi Amano and Shuji Nakamura made the first blue LEDs in the early 1990s.
LEDs are basically semiconductors that have been built so they emit light when they’re activated. Different chemicals give different LEDs their colors. Engineers made the first LEDs in the 1950s and 60s. Early iterations included laser-emitting devices that worked only when bathed in liquid nitrogen. At the time, scientists developed LEDs that emitted everything from infrared light to green light… but they couldn’t quite get to blue. That required chemicals, including carefully-created crystals, that they weren’t yet able to make in the lab.
Once they did figure it out, however, the results were remarkable. A modern white LED lightbulb converts more than 50 percent of the electricity it uses into light. Compare that to the 4 percent conversion rate for incandescent bulbs, and you have one efficient bulb. Besides saving money and electricity for all users, white LEDs’ efficiency makes them appealing for getting lighting to folks living in regions without electricity supply. A solar installation can charge an LED lamp to last a long time, allowing kids to do homework at night and small businesses to continue working after dark.
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| Professors Akasaki, Hiroshi Amano and Shuji Nakamura(from left to right) |
A modern white LED lightbulb converts more than 50 percent of the electricity it uses into light. Compare that to the 4 percent conversion rate for incandescent bulbs.
LEDs also last up to 100,000 hours, compared to 10,000 hours for fluorescent lights and 1,000 hours for incandescent bulbs. Switching more houses and buildings over to LEDs could significantly reduce the world’s electricity and materials consumption for lighting.
A white LED light is easy to make from a blue one. Engineers use a blue LED to excite some kind of fluorescent chemical in the bulb. That converts the blue light to white light.
Two of this year’s prize winners, Isamu Akasaki and Hiroshi Amano, worked together on producing high-quality gallium nitride, a chemical that appears in many of the layers in a blue LED. The previous red and green LEDs used gallium phosphide, which was easier to produce. Akasaki and Amano discovered how to add chemicals to gallium nitride semiconductors in such a way that they would emit light efficiently. The pair built structures with layers of gallium nitride alloys.
The third prize-winner, Shuji Nakamura, also worked on making high-quality gallium nitride. He figured out why gallium nitride semiconductors treated with certain chemicals glow. He built his own gallium nitride alloy-based structures.
Both Nakamura’s and Akasaki’s groups will continue to work on making even more efficient blue LEDs, the committee for the Nobel Prize in physics said in a statement. Nakamura is now a professor at the University of California, Santa Barbara, although he began his LED research at a small Japanese chemical company called Nichia Chemical Corporation. Akasaki and Amano are professors at Nagoya University in Japan.
Although red and green LEDs had been around for many years, blue LEDs were a long-standing challenge for scientists in both academia and industry.
Without them, the three colors could not be mixed to produce the white light we now see in LED-based computer and TV screens. Furthermore, the high-energy blue light could be used to excite phosphorus and directly produce white light - the basis of the next generation of light bulb.
Today, blue LEDs are found in people's pockets around the world, inside the lights and screens of smartphones.
White LED lamps, meanwhile, deliver light to many offices and households. They use much less energy than both incandescent and fluorescent lamps.
That improvement arises because LEDs convert electricity directly into photons of light, instead of the wasteful mixture of heat and light generated inside traditional, incandescent bulbs. Those bulbs use current to heat a wire filament until it glows, while the gas discharge inside fluorescent lamps also produces both heat and light.
Inside an LED, current is applied to a sandwich of semiconductor materials, which emit a particular wavelength of light depending on the chemical make-up of those materials.
Four years later Prof Nakamura made a similar breakthrough, while he was working at the chemical company Nichia. Instead of a special substrate, he used a clever manipulation of temperature to boost the growth of the all-important crystals.
In the future, engineers may make white LEDs by combining red, green, and blue ones, which would make a light with tunable colors.
Well done
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