New! Sign up for our free email newsletter.
Science News
from research organizations

Discovery of an atomic electronic simulator

Not just another computer chip

Date:
October 15, 2018
Source:
University of Alberta
Summary:
Targeting applications like neural networks for machine learning, a new discovery is paving the way for atomic ultra-efficient electronics, the need for which is increasingly critical in our data-driven society. The key to unlocking untold potential for the greenest electronics? Creating bespoke atomic patterns to in turn control electrons.
Share:
FULL STORY

Targeting applications like neural networks for machine learning, a new discovery out of the University of Alberta and Quantum Silicon Inc. in Edmonton, Canada is paving the way for atomic ultra-efficient electronics, the need for which is increasingly critical in our data-driven society. The key to unlocking untold potential for the greenest electronics? Creating bespoke atomic patterns to in turn control electrons.

"Atoms are a bit like chairs that electrons sit on," said Robert Wolkow, physics professor and principal investigator on the project. "Much as we can affect conversations at a dinner party by controlling the grouping of chairs and assigned seating, controlling the placement of single atoms and electrons can affect conversations among electronics."

Wolkow explained that while atomic control over structures is not uncommon, making custom patterns to create new useful electronic devices has been beyond reach. Until now.

Though the tools of nanotechnology have permitted exacting control over atom placement on a surface for some time, two limitations have prevented practical electronic applications: the atoms would only remain in place at cryogenic temperature and could only readily be achieved on metal surfaces that were not technologically useful.

First proof of concept

Part atomic machine, part electronic circuit, Wolkow and his team have recently created a proof-of-concept device, overcoming the two major hurdles preventing this technology from being available to the masses. Both the robustness and the required electrical utility are now in hand. Additionally, the structures can be patterned on silicon surfaces, meaning scaling up the discovery is also easily achievable.

"This is the icing on a cake we've been cooking for about 20 years," said Wolkow. "We perfected silicon-atom patterning recently, then we got machine learning to take over, relieving long suffering scientists. Now, we have freed electrons to follow their nature -- they can't leave the yard we created, but they can run around freely and play with the other electrons there. The positions the electrons arrive at, amazingly, are the results of useful computations."

Based on these results, construction has started on a scaled-up machine that simulates the workings of a neural network. Unlike normal neural networks embodied of transistors and directed by computer software, the atomic machine spontaneously displays the relative energetic stability of its bit patterns. Those in turn can be used to more rapidly and accurately train a neural network than is presently possible.


Story Source:

Materials provided by University of Alberta. Note: Content may be edited for style and length.


Journal Reference:

  1. Mohammad Rashidi, Wyatt Vine, Thomas Dienel, Lucian Livadaru, Jacob Retallick, Taleana Huff, Konrad Walus, Robert Wolkow. Initiating and monitoring the evolution of single electrons within atom-defined structures. Physical Review Letters, 2018 [abstract]

Cite This Page:

University of Alberta. "Discovery of an atomic electronic simulator." ScienceDaily. ScienceDaily, 15 October 2018. <www.sciencedaily.com/releases/2018/10/181015120853.htm>.
University of Alberta. (2018, October 15). Discovery of an atomic electronic simulator. ScienceDaily. Retrieved November 22, 2024 from www.sciencedaily.com/releases/2018/10/181015120853.htm
University of Alberta. "Discovery of an atomic electronic simulator." ScienceDaily. www.sciencedaily.com/releases/2018/10/181015120853.htm (accessed November 22, 2024).

Explore More

from ScienceDaily

RELATED STORIES