The pitch

The form of electrical energy that is required depends strongly on the function to be performed. For example, a laptop computer typically needs 18 V direct current (dc). The conversion from the 110 V alternating current (ac) outlet to the 18 V dc is performed by a voltage converter. The dc power from a photovoltaic panel needs to be converted to ac to feed into the grid by a circuit called an inverter. Such a dc-to-ac power conversion also occurs in hybrid cars where dc energy from the battery is converted to ac energy to drive the electric motors. Consequently power conversion is ubiquitous with an annual market value of over $7 billion growing at a compound annual growth rate of over 12.6%.

The devices being used for power conversion are Si-based diodes and transistors, predominantly metal oxide semiconductor field-effect transistors and insulated gate bipolar transistors. While Si has performed well in the past, it has reached its material limits for power conversion. Thus increases in efficiency are becoming more difficult to achieve. Inefficient electric power conversion results in hundreds of terawatts of lost energy across the electrical grid in the United States, equivalent to 318 coal-fired power plants. The cost to the U.S. economy is $40 billion annually, which represents over 10% of all the power generated in the United States today. The losses in electrical power conversion are larger than all the electricity produced from the alternative energy sources of power combined by over an order of magnitude. To eliminate these losses requires moving to a new materials system to produce an ideal switch, that is, the ability to hold large voltages when off and dissipate negligible loss when passing current in the on state.

According to the company Transphorm, the optimum and most economical materials to perform this function are based on gallium nitride. Transphorm’s GaN-based power solutions increase efficiency, reduce system size, and simplify overall product design and can eliminate up to 90% of all electric conversion losses from heating, ventilation, and air-conditioning systems (HVAC) and solar panels.

The technology

The power-conversion devices that are integrated into the final module solutions are based on the aluminum gallium nitride (AlGaN)/gallium nitride (GaN) heterostructure fabricated into both diodes and transistors. The transistor is a high-electron-mobility transistor. The cross section of the material structure and the device design of a typical device is shown in the figure. The current is carried by a two-dimensional electron gas possessing high electron mobility formed at the AlGaN/GaN interface to neutralize the positive charge that exists at the interface due to the polarization difference between the AlGaN and the GaN. This polarization difference (a materials property) increases almost linearly with Al composition enabling a simple tailoring of the electron density by material composition without the need for doping. This results in extremely high electron mobility, in excess of 2000 cm2V−1s−1 with charge densities typically around 1 × 1013cm−2. The resulting low resistance of the channel coupled by the high breakdown voltage enabled by the high breakdown field strength (>3 × 106cm−1; 10 times that of silicon because of the larger bond strength and bandgap of GaN) results in exceptionally high efficiencies of over 99.2% in converting 200 V dc to 400 V dc and 98.5% in a photovoltaic inverter both in the range of a kW of power at a high frequency of 100 kHz. These results demonstrate that the promise of high-eficiency GaN-based power conversion is now becoming a reality and the market penetration will continue to increase as the technology matures and the advantages of low-loss and small form factor drive new designs.

figure 1

The AlGaN/GaN heterostructure used to fabricate Transphorm’s diodes and transistors. The high-electron-mobility channel is also shown.