Blog
- Record-breaking molecular magnet 08/02/2022 Dilanthanide complexes could pave the way for a new breed of powerful permanent magnets
- Scientists Observe Quantum Spin Liquids: A State of Matter We've Never Seen Before 03/02/2022 An exotic and totally new state of matter called a quantum spin liquid has been hypothesized for decades, and now scientists have been able to observe it in a laboratory for the first time.
- A well-known iron-based magnet is also a potential quantum information material 01/02/2022 Scientists pursuing better performance in a well-known type of iron-based magnet also discovered wide-gap semiconducting behavior and a quantum state useful for quantum information processing—all in a single low-cost material that has been in existence for decades.
- Light could boost performance of fuel cells, lithium batteries and other devices 27/01/2022 Engineers from MIT and Kyushu University in Japan have demonstrated for the first time that light can be used to significantly improve the performance of fuel cells, lithium batteries and other devices that are based on the movement of charged atoms, or ions.
- In situ ion-exchange preparation methods developed for efficient electrocatalytic water oxidation 25/01/2022 Using a simple redox-precipitation approach, a research team has recently reported their synthesis of ultrathin NiCoFe-NDA (NDA=2,6-naphthalenedicarboxylic acid) nanosheets for high efficiency oxygen evolution reaction (OER) in anion exchange membrane electrolysis (AEMWE). Related results were published on Energy & Environmental Science.
- A room-temperature gate-tunable bipolar valley Hall effect in molybdenum disulfide/tungsten diselenide heterostructures 20/01/2022 Two-dimensional semiconductors have a valley degree of freedom that could be used as a platform for future optoelectronic devices. The valley Hall effect, caused by electrons in different valleys having opposite Berry curvatures, is important for making such devices, but has only been reported with plasmonic structures or at cryogenic temperatures, limiting practical application. Here we report the observation of the valley Hall effect at room temperature in a molybdenum disulfide/tungsten diselenide van der Waals heterostructure. We show that the magnitude and polarity of the valley Hall effect in the heterostructure are gate tunable, which can be attributed to the contribution of the opposite valley Hall effect from electrons and holes in different layers. We use this gate tunability to create a bipolar valleytronic transistor.
- Researchers probe the performance of high-temperature superconductor 18/01/2022 The next generation of superconducting magnets has the potential to revolutionize fields such as energy storage, particle accelerators and medicine. The magic behind these tools lies in the high-temperature superconducting (HTS) wires that power them.
- Changing the properties of ferroelectric materials by vacating a single oxygen atom 13/01/2022 Researchers in the Technion Department of Materials Science and Engineering have succeeded in changing a material's electrical properties by vacating an oxygen atom from the original structure. Possible applications include electronic-device miniaturization and radiation detection.
- Tuning a magnetic fluid with an electric field creates controllable dissipative patterns 11/01/2022 Researchers at Aalto University have shown that a nanoparticle suspension can serve as a simple model for studying the formation of patterns and structures in more complicated non-equilibrium systems, such as living cells. The new system will not only be a valuable tool for studying patterning processes but also has a wide range of potential technological applications.
- Quest to deliver ultra-fast and energy efficient magnetic recording moves step closer 06/01/2022 The quest to deliver ultra-fast and energy efficient magnetic recording could be a step closer to fruition, due to pioneering new research on all-optical switching of magnetization.
- Toward achieving megatesla magnetic fields in the laboratory 04/01/2022 Recently, a research team at Osaka University has successfully demonstrated the generation of megatesla (MT)-order magnetic fields via three-dimensional particle simulations on laser-matter interaction. The strength of MT magnetic fields is 1–10 billion times stronger than geomagnetism (0.3–0.5 G), and these fields are expected to be observed only in the close vicinity of celestial bodies such as neutron stars or black holes. This result should facilitate an ambitious experiment to achieve MT-order magnetic fields in the laboratory, which is now in progress.