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28th November 2019

1,000-times-faster fabrication of atomic-scale computers

A new atomic-scale manufacturing method could enable ultra-efficient computers.

 

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As computers continue to infiltrate almost every aspect of modern life, their negative impact on the environment grows. According to recent estimates, the electricity required to power today's computers releases a total of more than 1 gigatonne of carbon emissions to the atmosphere each year. Now, scientists have developed a new manufacturing process that could enable ultra-efficient, atomic-scale computers that store more data and consume 100 times less power.

Scientists have previously manipulated single atoms to make ultra-dense memory arrays for computers, which store more data in a much smaller space than conventional hard drives and consume much less power. In a technique known as hydrogen lithography, researchers can use the tip of a scanning tunnelling microscope (STM) to remove single atoms of hydrogen bonded to a silicon surface. The pattern of silicon atoms bound to or lacking a hydrogen atom forms a binary code that stores the data.

However, there is a bottleneck when rewriting the data, because the STM tip must pick up and deposit hydrogen atoms at precise locations. A research team led by Professor Robert Wolkow, from the Department of Physics at the University of Alberta in Canada, wanted to develop a more efficient method to rewrite atomic memory arrays.

 

atomic scale manufacturing future technology
Researchers rewrote the binary data in the first line of a 24-bit memory array
(top image, red arrow) using molecules of hydrogen to encode the letter "M" (bottom image).

 

The researchers prepared silicon surfaces covered with hydrogen atoms. With hydrogen lithography, they removed certain atoms to write data. The scientists found that by taking away an extra hydrogen atom next to a bit they wanted to rewrite, they could create a reactive site that attracted hydrogen gas that was infused into the chamber. Binding of a single hydrogen gas (H2) molecule to the two adjacent sites erased the sites so that a new binary code could be written.

Using hydrogen gas as a "molecular eraser" to rewrite the data was much faster and easier than bringing in individual hydrogen atoms on an STM tip. The team demonstrated the technique's ability to rewrite a small 24-bit memory array. The new method allows 1,000-times-faster fabrication of atomic-scale computers, making them ready for real-world manufacture, the researchers say.

Their work appears this week in the journal ACS Nano.

 

 

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