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Researchers Koichiro Yaji and Shunsuke Tsuda at the National Institute for Materials Science (NIMS) in Japan have developed an improved type of microscope that can visualise key aspects of electron spin states in materials. Their work was published in the journal Science and Technology of Advanced Materials: Methods (STAM-M).
The quantum mechanical property of electrons called spin is more complex than the spin of objects in our everyday world. The spin states of electrons impact the electronic and magnetic behaviour of the materials they are part of.
The technology developed by Yaji and Tsuda is known as imaging-type spin-resolved photoemission microscopy (iSPEM). It uses the interaction of light with the electrons in a material to detect the relative alignment of the electron spins. It is particularly focused on electron spin polarisation — the extent to which electron spins are collectively aligned in a specific direction.
The team’s iSPEM machine consists of three interconnected ultra-high vacuum chambers for preparing and analysing the sample. Electrons are emitted from the sample by absorbing light energy, accelerated through the apparatus, and then analysed by interaction with a spin filter crystal. The results are displayed as images, which experts can use to glean the necessary information about the electron spin states in the sample.
“Compared to conventional machines, our iSPEM machine drastically improves the data acquisition efficiency by ten thousand times, with more than ten times improvement in spatial resolution,” says Yaji.
This advance could promote improvements in information processing and other electronic devices, as part of the fast-developing field known as spintronics. In spintronics applications, the spin state of electrons is utilised to store and process information, in addition to the traditional use of electric charge.
“This could lead to more energy-efficient and faster electronic devices, including quantum computers,” says Yaji. Applying the subtleties of quantum mechanical behaviour to computing is at the forefront of efforts to take computing powers to another level. Until now, most advances have been restricted to arcane demonstrations rather than practical applications. Mastering the understanding, control, and visualisation of electron spin could be a significant step forward.
“We now plan to use our machine to investigate the possibilities for developing a new generation of electron spin-based devices, because it will let us look into the properties of tiny and structurally complex samples previously hidden from view,” Yaji concludes.
Did you know?
In spintronics, the spin of the electrons is used to store and process information, in addition to the traditional use of electric charge.
Further information
Koichiro Yaji
[email protected]
National Institute for Materials Science (NIMS)
STAM-M Inquiries
[email protected]
