Device-Circuit Co-Design of Variation-Resilient Read/Write Drivers for Antiferromagnetic Tunnel Junction Memories

Co-designed STSA+, PD EQ+, and WD_WRITE circuits enable reliable picosecond AFMTJ switching with sub-10⁻⁶ BER/WER. AFMTJs achieve 6.9× faster writes and ~5× lower energy vs. MTJ at 0.7V, robust under 3D-stacked PVT variation.

#Spintronics #AFMTJ #MRAM

NV Quantum Dephasometry of Near-Field EM Fluctuations in Superparamagnetic CoFeB

NV center quantum dephasometry non-invasively probes superparamagnetic spin dynamics in 1.1nm CoFeB, revealing unconventional non-monotonic T2 temperature dependence from MHz-range EM fluctuations driven by thermally activated magnetic domain flipping.

#QuantumSensing #Spintronics #NVCenter

Geometry-Driven Spin Currents via Asymmetric Tunneling Barriers in Fermi-Hubbard Rings

Theoretical work shows spin-resolved circulating currents emerge in a 1D Fermi-Hubbard ring using only spin-independent asymmetric barriers—no magnetic fields required. Counter-propagating spin transport unlocked at resonant barrier-interaction conditions.

#Spintronics #QuantumMatter #Research

Spinterfaces of Cobaltocene with 2D Magnets CrI3 and Fe3GeTe2: First-Principles Study

DFT study reveals 100% spin polarization at cobaltocene/CrI3 interface and up to 3x enhanced intralayer exchange interactions, with stable adsorption geometries and strong directional magnetic anisotropy—promising for spin-transport and quantum applications.

#Spintronics #2DMaterials #Research

Spin gapless state in ferromagnetic CuMnO2: A first principles study Magnetic semiconductor CuMnO2 have potential applications in energy storage and electronic devices. Electronic band structures in the ferromagnetic ph…

Research : doi.org/10.1016/j.co...
@elsevierconnect.bsky.social

#Spintronics #MaterialsScience #Semiconductors #PhysicsResearch #Electronics #ComputationalScience #ResearchNews

Making Waves: RIXS Illuminates Elusive Carriers of Angular Momentum Using resonant inelastic x-ray scattering, scientists achieve the first direct observation of magnon spin currents.

Researchers at #NSLSII are pioneering new techniques to explore spin currents.

Their work will help advance the field of #spintronics, which leverages the spin of electrons to quickly and efficiently transmit information.

Electric current now controls electron “spin” – a tiny internal magnet – opening doors for faster, more efficient computing. ✨ #spintronics

Source: phys.org/news/2026-03-electric-cu...

#PhD #position at Uni Duisburg-Essen buff.ly/lhtygEc #Theoretical and #Computational #Physics; #neuromorphic #spintronics #research

[Open Access]
Role of hot phonons and layer geometry in spintronic terahertz emission
2025 Appl. Phys. Express 18 093001

iopscience.iop.org/article/10.3...

#APEX
#OpenAccess
#Physics
#terahertz
#spintronics
#thinfilm
#phonon

TU Dortmund Demonstrates Dual-Gate Control of Persistent Spin Helix in GaAs Quantum Wells

TU Dortmund used coordinated dual-gate tuning to switch persistent spin helix orientation in GaAs double quantum wells by inverting Rashba SOC while holding electron density constant, overcoming single-gate leakage limits.

#Spintronics #QuantumWells #News

Quantum materials breakthrough for energy-efficient data processing Spintronics – a technology that harnesses the electron’s magnetic quantum states to carry information – could pave the way for a new generation of ultra-energy-efficient electronics. Yet a major chall...

#Spintronics could pave the way for a new generation of ultra-energy-efficient #electronics. A breakthrough by researchers in Sweden opens the door to next-generation low-power data processing and memory technologies
#research #science #quantumphysics tinyurl.com/3ycx4v8v

#PhD #position at MLU in Halle (DE) buff.ly/2dW6Xhe #Spin and #orbital #transport on #ultrafast timescales; #spintronics #magnetism #research ; Martin Luther University Halle-Wittenberg

🔬 Japanese researchers found a way to detect Majorana particles — "phantom particles" that are their own antiparticle — using spin currents.
Published in Physical Review X. A new rival path to Microsoft's Majorana 1 chip.
#QuantumComputing #Majorana #Spintronics #PhysRevX

Illustration of magnetic switching induced by an electric current.

𝐌𝐚𝐠𝐧𝐞𝐭𝐢𝐬𝐦 𝐬𝐰𝐢𝐭𝐜𝐡𝐢𝐧𝐠 𝐰𝐢𝐭𝐡𝐢𝐧 140 𝐩𝐢𝐜𝐨𝐬𝐞𝐜𝐨𝐧𝐝𝐬 𝐢𝐧 𝐚𝐧𝐭𝐢𝐟𝐞𝐫𝐫𝐨𝐦𝐚𝐠𝐧𝐞𝐭𝐢𝐜𝐬 [via U of Tokyo] 🧪⚛️🧭⚙️

"switching occurs in two [ways]: one driven by a thermal process under a large current and another without substantial heating under a #weak #current."

www.s.u-tokyo.ac.jp/en/press/109...

#spintronics #MRAM

#postdoc #position at Spintec (FR) buff.ly/CRoDRy7 Applied #spintronics #MTJ – Si-embedded vertical magnetic tunnel junctions

#postdoc #position at LPCNO (Toulouse, FR) buff.ly/vM0cZpF #2D #spintronics #optospintronics ; Spin–charge interconversion in proximity-engineered #graphene probed by opto-spintronics

#position #research #scientist at Spintec buff.ly/VvaytdV #MTJ based #devices (#MRAM, #sensors) #spintronics

From spintronics to magnetic dynamics and magnetic materials/devices for computing, Luqiao helps shape JMMM with reviews that aim to be efficient, constructive, and fair. 💬 Have a question about publishing in JMMM? Ask below 👇 #JMMM #Magnetism #Spintronics #MagneticMaterials

Resonant X-Ray Scattering Unlocks the Secrets of Spin Flow Researchers used sophisticated resonant X-ray scattering to directly view spin wave currents. The findings were published in Nature.

Scientists just used resonant X-ray scattering to directly observe spin wave currents for the first time. Could this breakthrough enable faster, cooler, spin-based electronics? Discover how RIXS unlocks the secrets of spin flow: www.azoquantum.com/News.aspx?ne... #Spintronics #QuantumTech

Twist Angle Control Generates Large-Scale Skyrmions in Layered 2D Antiferromagnets Researchers from the University of Edinburgh and collaborators have discovered that slightly twisting atomically thin magnetic crystals can generate unexpectedly large magnetic structures known as skyrmions. The study, published in Nature Nanotechnology, focuses on twisted double bilayer chromium triiodide (CrI3), a two-dimensional antiferromagnetic material. While previous work in moiré engineering showed that small angular mismatches between stacked layers can dramatically alter electronic properties, magnetism was generally expected to follow the same small-scale moiré pattern created by the overlapping lattices. However, using scanning nitrogen-vacancy magnetometry, the team observed magnetic textures extending up to approximately 300 nanometers—around ten times larger than the underlying moiré wavelength. Surprisingly, the size of these magnetic textures did not simply increase as the twist angle decreased. Instead, the skyrmion-like structures reached their maximum size near a twist angle of 1.1 degrees and disappeared above about 2 degrees. This counterintuitive behavior indicates that the magnetism does not merely mirror the moiré pattern but emerges from a balance of competing interactions, including exchange coupling, magnetic anisotropy, and Dzyaloshinskii–Moriya interactions. Large-scale spin dynamics simulations confirmed the formation of extended Néel-type antiferromagnetic skyrmions spanning multiple moiré cells. The researchers describe this phenomenon as “super-moiré spin order,” emphasizing that small atomic-scale rotations can stabilize topological magnetic states across much larger distances. These findings have potential implications for spintronics, where skyrmions are valued for their stability, small size, and low energy requirements for manipulation. Because these structures can be generated simply by controlling the twist angle—without complex fabrication techniques or strong electric currents—the approach could provide a geometry-based pathway toward low-power, energy-efficient computing technologies beyond conventional CMOS systems.

Twist Angle Control Generates Large-Scale Skyrmions in Layered 2D Antiferromagnets

🤖 IA: It's not clickbait ✅
👥 Usuarios: It's not clickbait ✅

#spintronics #2dmaterials #skyrmions

View full AI summary:

#postdoc #position #spintronics at International Iberian Nanotechnology Laboratory buff.ly/WfslF9o Exploratory Development of Innovative Beyond State-of-the-Art #Spintronic #Devices; #fabrication #research #MTJ #TMR #sensor #bioapplication

Forget charge—data's next frontier is electron spin! “Spintronics” could lead to faster, more efficient devices by harnessing a fundamental quantum property. 💡 #spintronics

Source: phys.org/news/2026-02-electrical-...

💎 While the world fights over AI chips, Japan is quietly building what comes NEXT.
Ultra-low-power MRAM via spintronics. Diamond semiconductors for extreme heat. Japan leads in post-silicon tech that could reshape computing.
#MRAM #DiamondSemiconductor #Spintronics

🗣️ #ICN2Seminars

We invite you to this 𝐬𝐞𝐦𝐢𝐧𝐚𝐫 by Prof. Farkhad G. Aliev (@uam.es), hosted by Dr Juan F. Sierra.

📆 27/02/2026
⏰ 12 PM 
📍 ICMAB Campus UAB (Spain)
📝 Register here to attend! 👉 https://f.mtr.cool/tvbliyqlgo
🔃 Sharing is appreciated!

#Spintronics

電荷の時代はもう終わり？私たちの生活を一変させる「スピントロニクス」5つの衝撃的な真実 1. イントロダクション：電子の「隠れた力」への招待現代のテクノロジーは、電子の「電荷（電気的な性質）」を操ることで発展してきました。しかし、この電荷ベースの電子工学（エレクトロニクス）は、今、物理的な限界に直面しています。電子の移動は、例えるなら「摩擦熱を生み出す不器用な水流」のようなものです。デバイスが微細化するほど、この摩擦による発熱と電力消費が、コンピューティングの進化を阻む巨大な壁となっ...

スピントロニクス革命: 電子スピンとコンピューティングの未来
#spintronics #TDK #MRAM #japan #computing #AI #techology #スピントロニクス
paragraph.com/@bitcap/%E9%...

Journées de la Matière Condensée 2026

#event Journées de la Matière Condensée 26-30 Oct 2026 Toulouse (FR) buff.ly/IPVASk3 several #magnetic symposia; #magnetism #spintronics #quantum #magnet #physics #condensed #matter

📝 Check out our new paper about Spin-Orbitronics effects at interfaces and chiral molecules ! Kumari and the team are exploring the possibility of generation and propagation or orbital currents in two representative systems.

#OBELIXproject #spintronics #orbitronics #EUfunded #research #newpaper

Magnetic skyrmions: A new frontier for quantum computing Nanoscale, topologically protected whirlpools of spins have the potential to move from applications in spintronics into quantum science.

Magnetic skyrmions: A new frontier for quantum computing

Nanoscale, topologically protected whirlpools of spins have the potential to move from applications in #spintronics into #quantum science.

physicstoday.aip.org/features/mag...

#PhD #position at ICN2 (Barcelona) buff.ly/hH8GQpQ #Spin–Orbit Torques in van der Waals #Heterostructures; #spintronics #SOT #torque #2Dmagnet #graphene

#PhD #position at ICN2 (Barcelona) buff.ly/fTnc6kK #Spintronic Control of Many-Body #Interactions in Flat-Band #Graphene; #research #spintronics