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March 29, 2023

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Magnon-based computation could signal computing paradigm shift

by Celia Luterbacher, Ecole Polytechnique Federale de Lausanne

Magnon-based computation could signal computing paradigm shift
Magnonic memory effect-Reading and writing of magnetic bits by spin
waves. a Two lattices of Py nanostripes (bistable magnetic bits)
underneath coplanar waveguides (CPWs) on an insulating YIG film. b
Depending on the spin-wave (SW) amplitude bit writing (I and II),
reading (III) and data replication (IV) are achieved without charge
flow. c-e Transmission signals Mag(S21) are taken at three different
power levels P[irr] by applying electromagnetic (em) waves via a
vector network analyzer (VNA). Analyzing signal strengths of mode
branches (blue and orange dashed lines), fields H[C1] and H[C2] are
extracted reflecting bit reversal. The red dashed lines
indicate + 14mT. Yield of bit writing (dark) underneath f CPW1 and g
CPW2 by propagating SWs at m[0]H[B] = + 14 mT. The 50% transition
power levels P[C1] and P[C2], respectively, are marked as black dots.
The error bars indicate the 70% and 30% transitions (Methods). h Mag(
S11) at P[sens] and i Mag(S21) taken at +14 mT. In i, bits at CPW1
and CPW2 were magnetized to state 1. Credit: Nature Communications
(2023). DOI: 10.1038/s41467-023-37078-8

Like electronics or photonics, magnonics is an engineering subfield
that aims to advance information technologies when it comes to speed,
device architecture, and energy consumption. A magnon corresponds to
the specific amount of energy required to change the magnetization of
a material via a collective excitation called a spin wave.

Because they interact with magnetic fields, magnons can be used to
encode and transport data without electron flows, which involve
energy loss through heating (known as Joule heating) of the conductor
used. As Dirk Grundler, head of the Lab of Nanoscale Magnetic
Materials and Magnonics (LMGN) in the School of Engineering explains,
energy losses are an increasingly serious barrier to electronics as
data speeds and storage demands soar.

"With the advent of AI, the use of computing technology has increased
so much that energy consumption threatens its development," Grundler
says. "A major issue is traditional computing architecture, which
separates processors and memory. The signal conversions involved in
moving data between different components slow down computation and
waste energy."

This inefficiency, known as the memory wall or Von Neumann
bottleneck, has had researchers searching for new computing
architectures that can better support the demands of big data. And
now, Grundler believes his lab might have stumbled on such a "holy
grail".

While doing other experiments on a commercial wafer of the
ferrimagnetic insulator yttrium iron garnet (YIG) with nanomagnetic
strips on its surface, LMGN Ph.D. student Korbinian Baumgaertl was
inspired to develop precisely engineered YIG-nanomagnet devices. With
the Center of MicroNanoTechnology's support, Baumgaertl was able to
excite spin waves in the YIG at specific gigahertz frequencies using
radiofrequency signals, and--crucially--to reverse the magnetization of
the surface nanomagnets.

"The two possible orientations of these nanomagnets represent
magnetic states 0 and 1, which allows digital information to be
encoded and stored," Grundler explains. Credit: Ecole Polytechnique
Federale de Lausanne

A route to in-memory computation

The scientists made their discovery using a conventional vector
network analyzer, which sent a spin wave through the YIG-nanomagnet
device. Nanomagnet reversal happened only when the spin wave hit a
certain amplitude, and could then be used to write and read data.

"We can now show that the same waves we use for data processing can
be used to switch the magnetic nanostructures so that we also have
nonvolatile magnetic storage within the very same system," Grundler
explains, adding that "nonvolatile" refers to the stable storage of
data over long time periods without additional energy consumption.

It's this ability to process and store data in the same place that
gives the technique its potential to change the current computing
architecture paradigm by putting an end to the energy-inefficient
separation of processors and memory storage, and achieving what is
known as in-memory computation.
[INS::INS]

Optimization on the horizon

Baumgaertl and Grundler have published the groundbreaking results in
the journal Nature Communications, and the LMGN team is already
working on optimizing their approach.

"Now that we have shown that spin waves write data by switching the
nanomagnets from states 0 to 1, we need to work on a process to
switch them back again--this is known as toggle switching," Grundler
says.

He also notes that theoretically, the magnonics approach could
process data in the terahertz range of the electromagnetic spectrum
(for comparison, current computers function in the slower gigahertz
range). However, they still need to demonstrate this experimentally.

"The promise of this technology for more sustainable computing is
huge. With this publication, we are hoping to reinforce interest in
wave-based computation, and attract more young researchers to the
growing field of magnonics."

More information: Korbinian Baumgaertl et al, Reversal of nanomagnets
by propagating magnons in ferrimagnetic yttrium iron garnet enabling
nonvolatile magnon memory, Nature Communications (2023). DOI: 10.1038
/s41467-023-37078-8

Journal information: Nature Communications  

Provided by Ecole Polytechnique Federale de Lausanne  

Citation: Magnon-based computation could signal computing paradigm
shift (2023, March 29) retrieved 2 April 2023 from https://phys.org/
news/2023-03-magnon-based-paradigm-shift.html
This document is subject to copyright. Apart from any fair dealing
for the purpose of private study or research, no part may be
reproduced without the written permission. The content is provided
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