Pure red LEDs fulfill a primary goal

This MOCVD machine is the key technology needed to achieve bright red LEDs.

© 2020 KAUST

Making pure red LEDs from nitride crystals is a goal that has so far frustrated engineers. However, these LEDs are vital for building the next generation of energy-efficient micro-LED displays to follow OLED displays and for creating lighting with color tuning. Now, for the first time, a team of electrical engineers at KAUST has succeeded in making these LEDs.

"Electrical engineers can already make bright LEDs using varying materials to produce different colors. But to improve display technologies, engineers must integrate the three primary color LEDs, red, green and blue, onto one chip," explains Daisuke Iida, an electrical engineer at KAUST. This means they need to find one material that is suitable for manufacturing all three colors. The material should be able to produce each color with high intensity, and ideally, it should have a high-power output, but use relatively little battery voltage.

The best candidates for generating all three colors are a family of compounds called nitride semiconductors. These are crystals containing nitrogen that in theory can be used to create LEDs that produce light with wavelengths between ultraviolet and infrared, which includes the entire visible spectrum. Engineers usually use gallium nitride to make blue and green LEDs, but they have struggled to make bright red LEDs with this crystal. “Red vision has been almost impossible—other groups have only really succeeded in making orange, not apple red,” says group leader, Kazuhiro Ohkawa. “Now, we have developed a crystal growth system to realize pure red LEDs.”

KAUST CEMSE EE ECODEVICES Primary Color LEDs Blue Green And Red Onto One Chip
To improve display technologies, engineers must integrate the three primary color LEDs, blue, green and red, onto one chip. © 2020 KAUST

Replacing a large portion of the gallium with the element indium gives the desired red, but it is hard to do because indium easily evaporates from the crystal. So Iida, Ohkawa and colleagues created a reactor with extra indium vapor above the crystal’s surface, a process known as metalorganic vapor-phase deposition. This added pressure prevents the indium in the crystal from escaping. “This gives us a higher indium concentration at the surface,” says Ohkawa. “That’s our secret!”

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