Antiferromagnets have attracted extensive interest as a material platform in spintronics. So
far, antiferromagnet-enabled spin–orbitronics, spin-transfer electronics and spin caloritronics …

Control and detection of spin order in ferromagnetic materials is the main principle enabling
magnetic information to be stored and read in current technologies. Antiferromagnetic …

The elementary spin excitations in strongly magnetic materials are collective spin deviations,
or spin waves, whose quanta are called magnons. Interest in the experimental and …

Spin–orbit torques arising from the spin–orbit coupling of non-magnetic heavy metals allow
electrical switching of perpendicular magnetization. However, the switching is not purely …

Antiferromagnetic materials could represent the future of spintronic applications thanks to
the numerous interesting features they combine: they are robust against perturbation due to …

Antiferromagnetic materials are internally magnetic, but the direction of their ordered
microscopic moments alternates between individual atomic sites. The resulting zero net …

Understanding spin-lattice coupling represents a key challenge in modern condensed
matter physics, with crucial importance and implications for ultrafast and two-dimensional …

We report the direct observation of strong coupling between magnons and phonons in a two-
dimensional antiferromagnetic semiconductor FePS 3, via magneto-Raman spectroscopy at …

Spin insulatronics covers efforts to generate, detect, control, and utilize high-fidelity pure
spin currents and excitations inside magnetic insulators. Ultimately, the new findings may …

Spin pumping and spin-transfer torques are two reciprocal phenomena widely studied in
ferromagnetic materials. However, pumping from antiferromagnets and its relation to current …