Spin electronics is a rapidly emerging field which is based on taking advantage of the unique properties of the spin of the electron, the nucleus and other fundamental particles, as well as that of the photon. Spin electronics has special importance as conventional electronics reaches its physical limitations.
Novel sensing, memory and logic devices, which rely on generating, manipulating and detecting the electron's spin, as well as using currents of spin-polarized electrons to manipulate magnetization in the form of magnetic nanoelements and magnetic domain walls, have emerged in recent years.

Spin electronic devices in the form of highly sensitive read sensors for magnetic recording have been a key component of high capacity magnetic disk drives for more than a decade: they enabled a vast increase in the storage capacity of disk drives by several orders of magnitude and are key to today's information age.

Solid state memory devices such as Magnetic Random Access Memory (MRAM) have recently entered the market. Other exciting possibilities relate to very dense and high performance memory-storage devices such as Racetrack Memory, as well as low power magnetic logic, and applications of spintronic sensing devices such as diagnostic biomagnetic lab-on-a-chip devices. Many of these applications require the integration of magnetic and semiconducting materials and a fundamental understanding of both magnetic and semiconductor physics and technology: this is especially important if spin electronics is to become the electronics of the future.

Spin electronics encompasses a multidisciplinary research effort involving magnetism, semiconductor electronics, materials science, chemistry and biology. SPIN aims to provide a forum for the presentation of research and review articles of interest to all researchers in the field.

The scope of the journal includes (but is not necessarily limited to) the following topics:

Spin related quantum computing
Quantum computing hardware: superconductivity, optical quantum, ion trap, semiconductor, topological quantum computing, etc.
Quantum computing applications: quantum chemistry, quantum finance, quantum artificial intelligence, etc.
Quantum simulation theory and experiment
Materials
Metals
Heusler compounds
Complex oxides: antiferromagnetic, ferromagnetic
Dilute magnetic semiconductors
Dilute magnetic oxides
High performance and emerging magnetic materials
Semiconductor electronics
Nanodevices
Fabrication
Characterization
Spin injection
Spin transport
Spin transfer torque
Spin torque oscillators
Electrical control of magnetic properties
Organic spintronics
Optical phenomena and optoelectronic spin manipulation
Applications and devices
Novel memories and logic devices
Lab-on-a-chip
Others
Fundamental and interdisciplinary studies
Spin in low dimensional system
Spin in medical sciences
Spin in other fields
Computational materials discovery