Spintronic devices for high-density memory and neuromorphic computing – a review
Spintronics is a growing research field that focuses on exploring materials and devices that take advantage of the electron’s “spin” to go beyond charge based devices. The most impactful spintronic device to date is a highly sensitive magnetic field sensor, the spin-valve, that allowed for a 10,00...
Saved in:
| Main Authors: | , , , , , , , , , , |
|---|---|
| Other Authors: | |
| Format: | Article |
| Language: | English |
| Published: |
2024
|
| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/176741 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Spintronics is a growing research field that focuses on exploring materials and devices that take
advantage of the electron’s “spin” to go beyond charge based devices. The most impactful spintronic
device to date is a highly sensitive magnetic field sensor, the spin-valve, that allowed for a 10,000-fold
increase in the storage capacity of hard disk drives since it was first introduced in a magnetic recording
read head in 1997. In about 2007, the original spin-valve that was based on spin-dependent scattering
in metallic magnetic/non-magnetic interfaces evolved to a closely related device in which the essential
physics changed to that of spin-dependent tunneling across ultra-thin insulating layers placed between
magnetic electrodes, but the basic spin-engineered structure remained largely unchanged. These latter
structures were proposed in 1995 as potential memory elements for a magnetic random-access memory
(MRAM) and the first demonstration of this possibility was made in 1999. It was only recently (about
2019) that MRAM became a mainstream foundry technology.
Compared with most conventional charge based electronic devices, spintronic devices have the
advantage of non-volatility, low-power consumption, and scalability to smaller dimensions. For these
reasons, spintronic devices are highly attractive for next-generation information memory-storage and
are promising for advanced applications such as in-memory computing. Furthermore, spintronics
allows for a unique high capacity, non-volatile, solid-state memory-storage device that relies on devices
that can store multiple digital bits in the form of a series of chiral domain walls that are moved at highspeed
using nanosecond long current pulses along magnetic nanowires. These devices also enable synaptic functionalities in neuromorphic computing and are therefore, potential hardware candidates
for artificial intelligence.
In this review article, recent advances in multi-state spintronic devices are discussed. The review
starts with an introduction followed by a discussion on using domain-walls for achieving multiple
states for memory and neuromorphic computing. In the next section, achieving multiple levels based
on domain nucleation are discussed. Subsequent discussions review the use of magnetic pillars, and
other schemes for achieving high-density memory. The prospects of spintronic devices in neuromorphic
computing for artificial intelligence (AI) are also presented. The outlook and directions for new
research are provided at the end. |
|---|