Scientists use gallium oxide in high power semiconductor fabrication

  

Flat transistors are at their limits, so researchers have gone vertical. With a technique called metal-assisted chemical etching - or MacEtch - U. of I. engineers have used a chemical solution to etch semiconductors into 3D fin structures. The fins increase the surface area on a chip, allowing for more transistors or current, and can therefore handle more power while keeping the chip's footprint the same size.

Developed at the U. of I., the MacEtch method is seen as being superior to traditional "dry" etching techniques because it is far less damaging to delicate semiconductor surfaces, such as beta-gallium oxide, researchers said.

"Gallium oxide has a wider energy gap in which electrons can move freely," said the study's lead author Xiuling Li, a professor of electrical and computer engineering. "This energy gap needs to be large for electronics with higher voltages and even low-voltage ones with fast switching frequencies, so we are very interested in this type of material for use in modern devices. However, it has a more complex crystal structure than pure silicon, making it difficult to control during the etching process."

Applying MacEtch to gallium oxide crystals could benefit the semiconductor industry, Li said, but the advancement is not without hurdles.

"Right now, the etching process is very slow," she said. "Because of the slow rate and the complex crystal structure of the material, the 3D fins produced are not perfectly vertical, and vertical fins are ideal for efficient use of power."

In this study, the beta-gallium oxide substrate produced triangular, trapezoidal and tapered fins, depending on the orientation of metal catalyst layout relative to the crystals. Although these shapes are not ideal, the researchers were surprised to find that they still do a better job conducting current than the flat, unetched beta-gallium oxide surfaces.

"We are not sure why this is the case, but we are starting to get some clues by performing atomic-level characterisations of the material," Li explained. "The bottom line is that we have shown it is possible to use the MacEtch process to fabricate beta-gallium oxide, a potentially low-cost alternative to gallium nitride, with good interface quality."

Further research will need to address the slow etch rate, enable high performance beta-gallium oxide devices, and try to get around the problem of low thermal conductivity.

"Increasing the etch rate should improve the process's ability to form more vertical fins," according to Li. "This because the process will happen so quickly that it will not have time to react to all of the differences in crystal orientations."

The low thermal conductivity issue is a deeper problem, she said. "High-power electronics produce a lot of heat, and device researchers are actively seeking thermal engineering solutions. While this is a wide-open aspect in the semiconductor field right now, 3D structures like what we have demonstrated could help guide the heat out better in some device types."

The research findings have been published in the journal ACS Nano.