Single Atom Transistors Created

Image source: UNSW

In a remarkable feat of micro-engineering, physicists from the University of New South Wales (UNSW) in Australia  have created a working transistor consisting of a single atom placed precisely in a silicon crystal.  The work, which was published in Nature Nanotechnology could help provide a better foundation for scalable quantum computing.

The single atom transistor uses as its active component an individual phosphorus atom patterned between atomic-scale electrodes and electrostatic control gates.

This unprecedented atomic accuracy may yield the elementary building block for a future quantum computer with unparalleled computational efficiency.

Until now, single-atom transistors have been realised only by chance, where researchers either have had to search through many devices or tune multi-atom devices to isolate one that works.

“But this device is perfect”, says Professor Michelle Simmons, group leader and director of the ARC Centre for Quantum Computation and Communication Technology at UNSW. “This is the first time anyone has shown control of a single atom in a substrate with this level of precise accuracy.”

The microscopic device even has tiny visible markers etched onto its surface so researchers can connect metal contacts and apply a voltage, says research fellow and lead author Dr Martin Fuechsle from UNSW.

“Our group has proved that it is really possible to position one phosphorus atom in a silicon environment - exactly as we need it - with near-atomic precision, and at the same time register gates,” he says. 

The device is also remarkable, says Dr Fuechsle, because its electronic characteristics exactly match theoretical predictions undertaken with Professor Gerhard Klimeck’s group at Purdue University in the US and Professor Hollenberg’s group at the University of Melbourne, the joint authors on the paper.

The UNSW team used a scanning tunnelling microscope (STM) to see and manipulate atoms at the surface of the crystal inside an ultra-high vacuum chamber. Using a lithographic process, they patterned phosphorus atoms into functional devices on the crystal then covered them with a non-reactive layer of hydrogen.

Hydrogen atoms were removed selectively in precisely defined regions with the super-fine metal tip of the STM. A controlled chemical reaction then incorporated phosphorus atoms into the silicon surface.

Finally, the structure was encapsulated with a silicon layer and the device contacted electrically using an intricate system of alignment markers on the silicon chip to align metallic connects. The electronic properties of the device were in excellent agreement with theoretical predictions for a single phosphorus atom transistor.  

It is predicted that transistors will reach the single-atom level by about 2020 to keep pace with Moore’s Law, which describes an ongoing trend in computer hardware that sees the number of chip components double every 18 months.

As amazing an achievement as this is, this is only the start of providing a basis for either conventional or quantum computing. Researchers will need to build off of this technology to develop chips comprised of many P-31 transistors that are able to be used for computation. Even once that’s achieved, we’re still a long way from using chips based on this transistor in your home. Scanning Tunneling Microscopy is a pretty powerful tool for positioning individual atoms, but it’s also incredibly expensive to use as a basis for manufacturing.

UNSW Newsroom