Since all nerve cells are sensitive to electrical signals, Kim, a graduate student in Anikeeva's group, hypothesized that a magnetoelectric nanomaterial that can efficiently convert magnetization ...

However, these magnetic methods relied on genetic modifications and can’t be used in humans. Since all nerve cells are sensitive to electrical signals, Kim, a graduate student in Anikeeva’s group, ...

These devices could serve as valuable tools for biomedical research and may have potential for clinical applications in the ...

1b) and spin chirality have recently been recognized as important alternatives for creating large magnetoelectric coupling. Some materials with specific spin arrangements on geometrically ...

Advances in one area can unwittingly produce improvements in an entirely different field. Industrially manufactured multilayer capacitors (MLCs) are 1-cent electronic components 1 (Fig. 1a,b) that ...

Since all nerve cells are sensitive to electrical signals, Kim, a graduate student in Anikeeva's group, hypothesized that a magnetoelectric nanomaterial that can efficiently convert magnetization ...

Spurred by advances in energy-harvesting materials, a new generation of advanced implantable biomedical devices is emerging ...

The team also demonstrated that these domain walls can be moved using an electric field, thanks to a phenomenon called magnetoelectric coupling, where magnetic and electric properties are ...

The team also demonstrated that these domain walls can be moved using an electric field, thanks to a phenomenon called ...

To further miniaturize antennas, researcher managed to design and fabricate acoustically actuated ultra-compact NEMS magnetoelectric antennas. Instead of designing antennas at the electromagnetic wave ...

“This means that the materials’ magnetoelectric response is also isotropic – it depends solely on the direction of the injected current and not on the crystals’ orientation,” Schröter says. “This ...

That's where the tiny "magnetoelectric nanodiscs" (MENDs) come in. Developed by scientists from MIT and Germany's Friedrich-Alexander University, the flat hexagonal particles are each just 250 ...