Described in the paper, “Parallel Communication with InGaN/GaN Micro-LEDs Using a CMOS Compatible Approach”, making LEDs directly on a 200 mm silicon substrate opens the way to producing a matrix of LEDs of a few microns that are individually controlled by dedicated CMOS circuits. (Jan. 31, 9:00 - 9:20 am PST, Moscone Center, Room 2002, Level 2 West)​

InGaN/GaN microLEDs are a strong candidate to enable high data-rate light communication because of their robustness, availability at large scale and ability to reach GHz scale bandwidth. Using them in an array enables massively parallel transmission leading to a high data-rate density. A CEA-Leti patented process to integrate a GaN LED matrix over a CMOS ASIC has also been developed. In this CMOS-compatible approach, the microLEDs’ integration was optimized by bonding them directly on top of a 200 mm silicon wafer and using GaN-based devices as both emitters and fast photodetectors.

“In order to address communication applications, we modulate LEDs at high frequency to reach a high data rate,” said Anthony Cibié, lead author of the paper. “Our aim is to use an array of LEDs to emit light and to detect it by an array of photodiodes, both made from GaN. We know how to fabricate thousands of pixels arrays, thus we can have thousands of parallel communication channels.”​

​Efficiency Improvement

​Previous work has shown that microLEDs’ efficiency decreases as their size goes from the millimeter to micrometer range, because the number of carriers that can diffuse and recombine non-radiatively at defective sidewalls increases. Therefore, passivating the non-radiative centers and minimizing carrier-diffusion length appears to be critical to producing high-efficiency microLEDs.

For this reason, CEA-Leti has focused for many years on improving microLED efficiency, particularly by focusing first on defects passivation and more recently by understanding the impact of carrier diffusion, which is the subject of the second paper.

The paper, “Influence of quantum well thickness on carrier diffusion length in InGaN quantum wells grown on sapphire, freestanding GaN, and Si”, highlights the strategy to reduce the InGaN/GaN LEDs’ efficiency drop that comes with smaller pixel size by understanding and controlling carrier diffusion. (Jan. 30, 9:20 - 9:40 am PST, Moscone Center, Room 2024 (Level 2 West).​​​

“In this presentation, we show experimentally that the diffusion length can be reduced by decreasing the thickness of the InGaN quantum well, as the theory predicts. In addition, we present a power-dependent, unexpected behavior of the diffusion observed in large quantum wells that may help us to understand the physics of the emitters,” said Simon Litschgi, lead author of the paper.

Litschgi noted that these phenomena were studied on several epitaxy substrates, including silicon. This paves the way to fabricating more efficient GaN microLED devices on 200 mm and 300 mm Si wafers, which is the most cost-effective industrial solution for display and communication applications. 

“As a leader in microLED technology, CEA-Leti has long-focused on developing cutting-edge display and light-communication systems that meet the needs of our business partners and help them shape the markets they serve,” said Laurent Fulbert, deputy head of CEA-Leti’s Optics and Photonics Division. “These two projects directly address the interests of our partners.”​​​

GaN LED emission and GaN photodiode reception have a huge potential for optical communications ​