Researchers from ICN2, ICMAB-CSIC and the Bulgarian Academy of Science have shown how the interaction with palladium diselenide (PdSe₂) can modify and enhance graphene’s spintronic performance. The team's finding improve existing understanding of spin dynamics in graphene-based van der Waals heterostructures and could be key for developing more efficient computing devices.

Van der Waals heterostructures are materials formed by combining layers of different ultra-thin materials stacked on top of each other. In recent years, these structures have proven to be very useful for studying and understanding unusual physical phenomena, making them promising candidates for the development of new technologies. The new study analyzed the interactions that occur in a graphene and palladium diselenide (PdSe₂) heterostructure. The team stresses: "Our results showed that PdSe₂ can induce significant changes in the spin transport properties and dynamics of graphene, providing new possibilities for controlling information-carrying spin currents”. These findings constitute an important step forward in elucidating spin physics in van der Waals heterostructures and could allow for spin-logic devices in the future.

Tohoku University researchers have observed an opto-magnetic torque approximately five times more efficient than in conventional magnets. This breakthrough could be extremely beneficial for the development of light-based spin memory and storage technologies.

Opto-magnetic torque is a method which can generate force on magnets, which can be used to change the direction of magnets by light more efficiently. By creating alloy nanofilms with up to 70% platinum dissolved in cobalt, the team discovered that the unique relativistic quantum mechanical effects of platinum significantly boost the magnetic torque.

While most multiferroics can't operate above room temperature, a team of researchers at Tohoku University demonstrated that terbium oxide Tb₂(MoO₄)₃ works as a multiferroic even at 160°C.

A material that loses its functionality due to heat (from the environment or generated by the device itself) has limited practical applications. This is the major Achilles heel of multiferroics—materials that possess close coupling between magnetism and ferroelectricity. This coupling makes multiferroics an attractive area of research, despite that weakness.

A joint research team, led by Professor Jeong Myung-hwa from Sogang University and Professors Lee Kyung-jin and Kim Gap-jin from the Korea Advanced Institute of Science and Technology (KAIST), has captured, for the first time, the phenomenon of quantum mechanical spin pumping occurring at room temperature.

With charge current,  as current flows, electrons collide with atoms inside the material, generating heat and increasing energy consumption. This lowers the efficiency of current generation. To address this, researchers worldwide are conducting studies on creating electronic devices using spin current. The research team focused on the spin pumping phenomenon where spin moves from a ferromagnet to a non-magnetic material due to precession.

Grenoble-based Nellow, a newly-founded deep tech company, has been awarded 2.5 million by the European Innovation Council. 

This funding will help it develop its innovative component, combining ferroelectricity and spintronics, which promises chips that consume 1000 times less energy. The component Nellow is developing is called Feso, and it combines ferroelectricity and spintronics - spinorbitronics, to be exact.

Researchers at the University of Utah and the University of California, Irvine (UCI), have set out to better understand a property known as spin-torque, that is crucial for the electrical manipulation of magnetization that’s required for the next generations of storage and processing technologies. 

The spintronic prototype device that exploits the anomalous Hall torque effect. Image from: University of Utah

The scientists have discovered a new type of spin–orbit torque, in a recent study that demonstrated a new way to manipulate spin and magnetization through electrical currents, a phenomenon that they’ve dubbed the anomalous Hall torque.

A University of Tokyo research team has shown that the direction of a spin-polarized current can be restricted to only one direction in a single-atom layer of a thallium-lead alloys when irradiated at room temperature. 

This discovery defies conventions as single-atom layers have been thought to be almost completely transparent, in other words, negligibly absorbing or interacting with light. The one-directional flow of the current observed in this study could enable functionality beyond ordinary diodes, paving the way for more environmentally friendly data storage and ultra-fine two-dimensional spintronic devices. 

Researchers from the National University of Singapore (NUS), working with teams from University of California, Kyoto University and others, have reported a breakthrough in the development of next-generation graphene-based quantum materials, opening new horizons for advancements in quantum electronics.

The innovation involves a novel type of graphene nanoribbon (GNR) named Janus GNR (JGNR). The material has a unique zigzag edge, with a special ferromagnetic edge state located on one of the edges. This unique design enables the realization of one-dimensional ferromagnetic spin chain, which could have important applications in quantum electronics and quantum computing.

Researchers at the Research Center for Materials Nanoarchitectonics (MANA) recently proposed a method to create ferroelectric-ferromagnetic materials, opening doors to advancing spintronics and memory devices.

In 1831, Michael Faraday discovered the fundamental connection between electricity and magnetism, demonstrating that a changing magnetic field induces electric current in a conductor. In a recent study, MANA researchers proposed a method for designing ferroelectric-ferromagnetic (FE-FM) materials, which exhibit both ferroelectric and ferromagnetic properties, enabling the manipulation of magnetic properties using electric fields and vice versa. Such materials are highly promising for spintronics and memory devices. The advantage of FE-FM materials, extremely rare in nature, is their ability to achieve the cross-control by relatively low electric and magnetic fields. The study, led by Principal Researcher Igor Solovyev from MANA, NIMS, included contributions from Dr. Ryota Ono from MANA, NIMS, and Dr. Sergey Nikolaev from the University of Osaka, Japan.

Here are some recent and popular spintronics industry and research news that you may find of interest:

• Researchers report "somersaulting spin qubits"
• Researchers develop non-thermal method to alter magnetization using XUV radiation
• Researchers tackle key obstacles to bringing 2D magnetic materials into practical use
• New EU-funded project applies spintronics to the field of artificial intelligence
• Intel unveils a highly promising MESO spintronics device architecture
• Researchers report a new type of magnetism called altermagnetism
• Researchers develop spin-selective memtransistors with magnetized graphene
• Researchers report spintronics-based probabilistic computers compatible with current AI
• Neuranics secures $2.3 million investment
• Researchers develop atomic-scale spin-optical laser
• Researchers use perovskite materials and light to control electron spins
• New $7.5M project to leverage atomic-scale defects for next-generation processing
• Singapore’s National Research Foundation gives 'substantial funding' for spintronics devices