Category Technology/Electronics

For the first time, researchers have simulated local magnetic anisotropy at the atomic level in a magnetic material based on experimental data. This figure shows changes in magnetic energy across individual iron and platinum atoms from an FePt nanoparticle.
Credit: Image courtesy of Markus Eisenbach and Nature

Barely wider than a strand of human DNA, magnetic nanoparticles – such as those made from iron and platinum atoms – are promising materials for next-generation recording and storage devices like hard drives. Building these devices from nanoparticles should increase storage capacity and density, but understanding how magnetism works at the level of individual atoms is critical to getting the best performance...

W. Mtangi et al., Control of Electrons’ Spin Eliminates Hydrogen Peroxide Formation During Water Splitting, Journal of the American Chemical Society (30 January 2017). DOI: 10.1021/jacs.6b12971

A big obstacle in the production of hydrogen through water splitting is that H2O2 is also formed, which affects the efficiency stability of the reaction and the stability of the production. Researchers have now succeeded in controlling the spin of electrons in the reaction and thereby almost fully suppress the production of hydrogen peroxide in the electrochemical cell.

Led by professors Bert Meijer (Eindhoven University of Technology) and Ron Naaman (Weizmann Institute), the researchers are the first to have specifically investigated the role of the spin – the internal magnetic moment – of electron...

Researchers have developed a new technology that could triple the resolution density of displays. The new technology could allow field-sequential color displays where a single subpixel can be quickly switched among red, green or blue. By eliminating the color filters traditionally used to spatially divide one pixel into red, green or blue subpixels, field-sequential color displays allow the three subpixels to become three independent pixels and thus triples the resolution density. Credit: Yuge Huang and Ruidong Zhu, CREOL, The College of Optics and Photonics, University of Central Florida

An international team of researchers has developed a new blue-phase liquid crystal that could enable televisions, computer screens and other displays that pack more pixels into the same space while also r...

This is the directional emission of light. Credit: TU Wien

Recently, surprising physical effects were observed using special microscopic waveguides for light. Such “photonic structures” currently are revolutionizing the fields of optics and photonics, and have opened up the new research area of “Chiral Quantum Optics.” What one learns at school is that light oscillates under a right angle (transversal) with respect to its direction of propagation. Among experts, however, it was already known that light behaves differently when it is confined strongly in the transversal plane using “photonic structures.” In particular, this is the case for special ultra-thin glass fibers which have a diameter of only a few hundred nanometers and which are thereby smaller than the wavelength of light...