Gallium nitride power device technology enables a new generation of power converters in space operating at higher frequencies, higher efficiencies, and greater power densities than everachievable before. GaN power devices can also exhibit superior radiation tolerance compared with Silicon MOSFETs depending upon their device design.

Power Electronics Europe
December, 2020
Read article

Discrete power transistors, whether silicon-based or GaN-on-silicon, are entering their final chapter. GaN-on-Si integrated circuits offer higher performance in a smaller footprint with significantly reduced cost and less engineering required. This article details how the ascent of GaN is redefining power conversion.

Bodo’s Power Systems
October, 2020
Read article

Just like life’s reality, when the aged leaves the center stage for the younger ones, Silicon is taking the bow. The advent and adoption of Gallium Nitride (GaN) have succeeded in gradually easing out the old reliable Silicon. For over four decades, power management efficiency and cost have improved steadily as innovations in power MOSFET structures, technology, and circuit topologies have kept pace with the growing need for electrical power. In the new millennium, however, the rate of improvement has slowed dramatically as the silicon power MOSFET approaches its theoretical bounds. At the same time, the new material, GaN is steadily progressing on its journey toward a theoretical performance boundary that is 6,000 times better than the aging silicon MOSFET and 300 times better than the best GaN products on the market today.

EEWeb
July 16, 2020
Read article

An integrated circuit made using GaN-on-Si substrates has been in production for over five years. The ultimate goal is to achieve a single component IC that merely requires a simple digital input from a microcontroller and produces a power output that drives a load efficiently, reliably under all conditions, in the smallest space possible, and economically. Discrete power transistors, whether silicon-based or GaN-on-Si, are entering their final chapter. Integrated GaN-on-Si can offer higher performance in a smaller footprint with significantly reduced engineering required.

IEEE Power Electronics Magazine
March 2020
Read article

Silicon power MOSFETs have not kept pace with the evolutionary changes in the power electronics industry where factors such as efficiency, power density, and smaller form factors are the main demands of the community. The power electronics industry has seen the theoretical limit of silicon MOSFETs reached and now needs to move to a new element. Gallium Nitride or GaN is a highly mobile semiconductor electron semiconductor (HEMT) that is proving to be a real added value in meeting new applications.

Power Electronics News
March 25, 2020
Read article

This article discussed an oft forgotten or little-noticed part of the spacecraft enabling travel into outer space---power management in the space vehicle. Wide bandgap semiconductors like gallium nitride (GaN), silicon carbide (SiC), as well as diamond, are looking to be the most promising materials for future electronic components since the discovery of silicon. These technologies, depending upon their design, offer huge advantages in terms of power capability (DC and microwave), radiation insensitivity, high temperature and high frequency operation, optical properties and even low noise capability. Therefore, wide bandgap components are strategically important for the development of next generation space-borne systems. eGaN devices are quickly gaining momentum in the space industry and we will see many more applications for them by NASA and commercial contractors in future programs like Artemis and other programs in countries around the globe pursuing efforts into Space.

Power Systems Design
November, 2019
Read article

Today’s GaN FETs are improving rapidly in size and performance. The benchmark devices are still 300 times away from their theoretical performance limits. The early GaN adopters needed the speed. Big examples were lidar systems for autonomous cars, drones, and robots, and 4G/LTE base stations. The volume has grown, and now GaN power devices are at a point where the prices are equivalent to the slower, bigger and aging power MOSFET. Thus, it is time for GaN’s frontal assault!

Bodo’s Power Systems
June 2019
Read article

In this episode of PSDtv Alex Lidow, Chief Executive Officer and Co-Founder of Efficient Power Conversion (EPC) is at APEC 2019 in Anaheim and discusses why their GaN on Silicon devices make Silicon now dead.

PSDtv
View video

Last week, Anker debuted a tiny new power brick, crediting its small size with the component it uses instead of silicon: gallium nitride (GaN). It’s the latest example of the growing popularity of this transparent, glass-like material that could one day unseat silicon and cut energy use worldwide.

The Verge
Read article

This scientist got his Ph.D 40 years ago who saved the world's 15% energy consumption at one time. He is continuing his journey of innovations now in discovering silicon's replacement material for humankind.

My father always taught me that the true worth of an individual is measured based on their contribution to society. As I entered graduate school in 1975 I knew my passion was in the field of semiconductors, and I felt my best contribution to society would come from finding a successor to silicon. I did my graduate work in Gallium Arsenide, but realized by the time I received my PhD in 1977 that Gallium Arsenide’s prospects were limited as a semiconductor due to the basic materials properties, I went to work applying everything I learned to making better devices in silicon.

Fortune China
June 15, 2017
Read article

As deep learning proliferates, the question of data center power density is once again on the rise, creating new business opportunities for specialized cloud services, hosted in facilities that can support north of 30 kW per rack, and companies in the power conversion space, who can tackle the density issue by making systems more energy efficient. Replacing silicon as the semiconductor material in power conversion chips with gallium nitrate, or GaN, leads to much smaller and more energy efficient devices that provide much faster switching.

Data Center Knowledge
February, 2017
Read article

Silicon -- the core ingredient in semiconductors and the driving force behind the electronics industry -- is reaching its limit, says Alex Lidow, CEO of Efficient Power Conversion Corporation. His Los Angeles-based company is investigating the capacity of gallium nitride (GaN) to disrupt the $400 billion (£277bn) silicon industry with its improved powers of semiconducting. "This is the first 
time that there is a semiconductor that is both lower cost and has a higher performance than silicon," Lidow says.

Wired Magazine
Emma Bryce
March 31, 2016
Read article

The effort to take advantage of gallium nitride is partly a response to technical and economic factors that have slowed improvement in silicon-based chips.  While companies are still finding ways to fabricate smaller transistors in silicon, reductions in cost and power consumption have been more difficult to achieve. But gallium-nitride circuits can switch on and off much more quickly than silicon and handle higher voltages, said Alex Lidow, EPC’s chief executive. That makes the material particularly good for chores that involve power conversion.

Wall Street Journal
June 22, 2015
Read article

Power conversion involves creating tiny devices that convert electricity from one form to another, enabling all manner of electrical gadgets to function. Till now, silicon had been the preferred medium for power conversion processors, but as that element reaches the limits of its efficiency, attention has focused on new materials.

Los Angeles Business Journal
June 21, 2015
Read article