Blog
- Microscopy method breaks barriers in nanoscale chemical imaging 22/05/2025 Today's super-resolution microscopes have made it possible to observe the nanoscale world with unprecedented detail. However, they require fluorescent tags, which reveal structural details but provide little chemical information about the samples being studied.
- Researchers develop full-color-emitting upconversion nanoparticle technology for ultra-high RGB display quality 20/05/2025 Dr. Ho Seong Jang and colleagues at the Extreme Materials Research Center at the Korea Institute of Science and Technology (KIST) have developed an upconversion nanoparticle technology that introduces a core@multi-shell nanostructure, a multilayer structure in which multiple layers of shells surround a central core particle, and enables high color purity RGB light emission from a single nanoparticle by adjusting the infrared wavelength.
- Latest 2D Chip: 6,000 Transistors, 3 Atoms Thick 16/05/2025 New circuits might find use in edge-computing chips
- Detecting the anomalous Hall effect without magnetization in a new class of materials 14/05/2025 An international research team led by Mayukh Kumar Ray, Mingxuan Fu, and Satoru Nakatsuji from the University of Tokyo, along with Collin Broholm from Johns Hopkins University, has discovered the anomalous Hall effect in a collinear antiferromagnet.
- Layered room-temperature altermagnet shows promise for advanced spintronics 08/05/2025 Traditionally, magnetic materials have been divided into two main categories: ferromagnets and antiferromagnets. Over the past few years, however, physicists have uncovered the existence of altermagnets, a new type of magnetic material that exhibits features of both antiferromagnets and ferromagnets.
- New mechanism uses photonic crystal for concentrating light on a chip 06/05/2025 Concentrating light in a volume as small as the wavelength itself is a challenge that is crucial for numerous applications. Researchers from AMOLF, TU Delft, and Cornell University in the U.S. have demonstrated a new way to focus light on an extremely small scale. Their method utilizes special properties of a photonic crystal and works for a broader spectrum of wavelengths than alternative methods. The researchers published their findings in Science Advances on April 18.
- Cientistas avançam no conhecimento da perovskita para produção de energia limpa 29/04/2025 Pesquisadores investigaram a espessura ideal do material envolvido na transformação de energia óptica e térmica em eletricidade
- Pt nano-catalyst with graphene pockets enhances fuel cell durability and efficiency 17/04/2025 The manufacturing and deployment of hybrid and electric vehicles is on the rise, contributing to ongoing efforts to decarbonize the transport industry. While cars and smaller vehicles can be powered using lithium batteries, electrifying heavy-duty vehicles, such as trucks and large buses, has so far proved much more challenging.
- A New Age of Electron Microscopy: Magnifying Possibilities with Automation 15/04/2025 Automated electron microscopy meets supercomputing in the web-based platform Distiller
- Scientists unveil new way to electrically control spin for ultra-compact devices using altermagnetic quantum materials 10/04/2025 Spintronics, an emerging field of technology, exploits the spin of electrons rather than their charge to process and store information. Spintronics could lead to faster, more power-efficient computers and memory devices. However, most spintronic systems require magnetic fields to control spin, which is challenging in ultracompact device integration due to unwanted interference between components. This new research provides a way to overcome this limitation.
- New superconducting state discovered: Cooper-pair density modulation 08/04/2025 Superconductivity is a quantum physical state in which a metal is able to conduct electricity perfectly without any resistance. In its most familiar application, it enables powerful magnets in MRI machines to create the magnetic fields that allow doctors to see inside our bodies. Thus far, materials can only achieve superconductivity at extremely low temperatures, near absolute zero (a few tens of Kelvin or colder).