There are many ways to define innovation. The Greeks are always a good place to start, and philosopher, Socrates advised: “The secret of change is to focus all of your energy, not on fighting the old, but building on the new.”

Addressing the same theme from a different angle, Albert Einstein is alleged to have commented: “The definition of insanity is doing the same thing over and over again but expecting different results.” I personally believe in creating a culture of innovation — one of the founding principles of our company. If an organisation encourages creative thinking from all its employees, new ideas will emerge, challenging the old, traditional ways. Creativity sparks further creativity and great strides can be made.

All my experience – and my instinct – tells me that innovation results from a deep knowledge base. Before Cambridge GaN Devices, I ran a team at Cambridge University for more than 30 years researching different materials and technologies. Many ideas – different configurations, contexts and geometries – that were developed for silicon are now being applied to gallium nitride. For example, superjunction technology and membrane technology are re-emerging as possibilities for GaN. Of course, there are brand new concepts that have been developed purely for GaN too. It is this thorough and detailed understanding and appreciation of materials and device physics that is enabling new power applications based on GaN.

With our background, GaN was a natural playing ground. It is a very interesting material, but I have to say that of all the materials I have studied – silicon, silicon carbide, diamond, gallium nitride - by far the most difficult is GaN. GaN is not only a wide bandgap material but its application in a heterojunction is what makes it special. Indeed, the use of a GaN/AlGaN structure, enables an interface quantum layer (2DEG) with concomitantly high electron charge and high mobility.  So, on one hand, GaN companies re-purpose all the developments that have been made in silicon over the past 70 years, and on the other hand GaN offers new avenues for innovation.

Furthermore, as opposed to silicon carbide, GaN enables integration. So, for example, intelligence, protection and sensing can be produced in GaN and delivered on the same chip as the HEMT. Of course, this is also possible in silicon, but only at low power. GaN permits integration at much higher power levels and much higher frequencies.

Will GaN replace silicon in other markets? Well, for applications where high power and high frequency are required, GaN is the best material. But digital electronics will mainly remain as silicon implementations because silicon has both n-channel and p-channel transistors. GaN has the 2DEG structure which is fantastic for making an n-channel transistor, but today there is no reliable equivalent hole gas structure that would enable the creation of a p-channel transistor in GaN. And because recombination times are very small, bipolar devices are also not possible in GaN, Therefore, for the time being at least, GaN will remain as a HEMT device only. But for this purpose, GaN is a fantastic, marvellous material.  It will be used for power applications from maybe 40V to about 1.2kV and is going to dominate in high-frequency applications. GaN is also interesting for RF and there are opportunities in optical applications such as LEDs.

Cambridge Gan Devices (CGD) has taken a completely novel – innovative – approach to the GaN market: we optimise the use of GaN integration. CGD adds intelligence, sensing and protection, making the gate extremely reliable, but at the same time keeping the simplicity of a highly efficient transistor.

This approach supports the two claims we make about our ICeGaN™ gallium-nitride (GaN) technology: that is easy to use, because our transistors can be driven in the same way as a silicon or silicon carbide device; and that it matches the reliability of silicon and silicon carbide.

As Thomas Edison once said: “There’s a way to do it better – find it.”