Using an electric field instead of an electric current (or a magnetic field) to tailor the
electronic properties of magnetic materials is promising for realizing ultralow‐energy …

Control of magnetization direction is essential for the wide application of ferromagnets; it
defines the signal size of memory and sensor. However, the magnetization itself causes a …

Electric control of topological magnetic phases has attracted extensive attention due to its
potential applications in energy-efficient spintronic devices. Here, using first-principles …

Multiferroics simultaneously possess two or more primary ferroic orders, such as magnetic,
ferroelectric, ferroelastic and ferrotoroidic orders. Cross-coupling among these multi-ferroic …

In recent years, the field of antiferromagnetic spintronics has been substantially advanced.
Electric‐field control is a promising approach for achieving ultralow power spintronic devices …

Multiferroic nanostructures have been attracting tremendous attention over the past decade,
due to their rich cross-coupling effects and prospective electronic applications. In particular …

Robust multi‐level spin memory with the ability to write information electrically is a long‐
sought capability in spintronics, with great promise for applications. Here, nonvolatile and …

Antiferromagnetic states with no stray magnetic fields can enable high-density ultra-fast
spintronic technologies. However, the detection and control of antiferromagnetic Néel …

Antiferromagnetic materials, which have ordered but alternating magnetic moments, exhibit
fast spin dynamics and produce negligible stray fields, and could be used to build high …

The introduction of magnetic moments to topological materials provides rich opportunities for
studying the interplay among magnetism, electron correlation, and topological orders, which …