This website uses cookies primarily for visitor analytics. Certain pages will ask you to fill in contact details to receive additional information. On these pages you have the option of having the site log your details for future visits. Indicating you want the site to remember your details will place a cookie on your device. To view our full cookie policy, please click here. You can also view it at any time by going to our Contact Us page.

Switchable electric and magnetic order promises low-energy computing

18 September 2015

A material that combines both electrical and magnetic order at room temperature may enable the development of low-energy computer memory technologies.

With the rapid growth of the Internet and Internet-enabled devices, there is a strong need for lower-energy data storage technologies (image: Shutterstock)

Scientists at the University of Liverpool have developed a new material that combines both electrical and magnetic order at room temperature, using a design approach which may enable the development of low-energy computer memory technologies.  It was achieved by designed control of the distribution of the atoms within the solid state, and holds promise for information storage and processing applications.

Information can be stored in computers in two distinct ways: one relies on the order of atomic-scale magnets in a solid material, the other of atomic-scale electrical charges. Both storing and manipulating this information costs energy, and with the rapid growth of the Internet and Internet-enabled devices, there is a strong need for lower-energy alternatives.

Materials with both electrical and magnetic order at room temperature have been hard to engineer because these two properties often have competing requirements," says Liverpool materials chemist, Professor Matthew Rosseinsky. “We report a new design approach that promises to allow the synthesis and tuning of families of these materials, which are important in the development of low-energy computer memory technologies.”

To make a single material that has these two distinct properties – magnetisation and electrical polarisation – is difficult because the electronic requirements for obtaining them in a material are typically contradictory: materials characteristics, such as the crystal structure or the atomic composition, which favour polarisation often disfavour magnetisation.

The new design approach developed by University of Liverpool researchers overcomes these difficulties.

The research, published in the journal, Nature, was funded by the UK Engineering and Physical Sciences Research Council, and involved collaboration with Trinity College Dublin.


Print this page | E-mail this page