Blog
- Team successfully demonstrates laser-induced monolayer graphene nanoprocessing 30/05/2023 Discovered in 2004, graphene has revolutionized various scientific fields. It possesses remarkable properties like high electron mobility, mechanical strength, and thermal conductivity. Extensive time and effort has been invested in exploring its potential as a next-generation semiconductor material, leading to the development of graphene-based transistors, transparent electrodes, and sensors.
- Ladder-like polymer that could halt electrical overheating divides opinion 25/05/2023 Questions raised over reported structure and whether the polymer can even perform as researchers hope
- Determining the elusive structure of the antihistamine Levocetirizine 23/05/2023 For pharmaceuticals, knowing the chemical composition is not enough—molecular geometry and crystal structure also play an important role in a drug's activity. By using a method based on electron diffraction, it has now been possible for a research team to determine the structure of Levocetirizine, as reported in the journal Angewandte Chemie. The advantage of this technique is that, unlike for X-ray crystallography, nanoscale crystals are sufficient.
- New research computes first step toward predicting lifespan of electric space propulsion systems 15/05/2023 Electric space propulsion systems use energized atoms to generate thrust. The high-speed beams of ions bump against the graphite surfaces of the thruster, eroding them a little more with each hit, and are the systems' primary lifetime-limiting factor. When ion thrusters are ground tested in an enclosed chamber, the ricocheting particles of carbon from the graphite chamber walls can also redeposit back onto the thruster surfaces. This changes the measured performance characteristics of the thruster.
- Electroplating method makes conductive nanostraws for injecting into and sampling from cells 09/05/2023 Nanosized straws made of conductive materials open tiny pores in cell membranes with very low voltage
- Prolonged photostability in hexagonal boron nitride quantum emitters 08/05/2023 Single-photon emitters are crucial building materials suited for optical quantum technologies. Among them, hexagonal boron nitride is a promising two-dimensional material that retains bright, room-temperature single-photon emitters. However, photo-instability is an existing challenge to facilitate applications of these properties in practice.
- Alloy takes on improbable 'negative pressure' structure 04/05/2023 A central feature of physical chemistry is materials’ tendency to adopt different structures at different pressures – including negative ones. But the idea of using negative pressure to reshape a material sounds experimentally impossible. But US researchers have developed a technique to drive alloys into structures that, in a pure material, would be stable only at negative pressures. The technique could allow the synthesis of a variety of new, potentially-useful materials previously thought almost inaccessible.
- Highly charged ions melt nano gold nuggets 02/05/2023 Normally, we have to make a choice in physics: Either we deal with big things—such as a metal plate and its material properties, or with tiny things—such as individual atoms. But there is also a world in between: The world of small but not yet tiny things, in which both effects of the macroscopic world and effects of the microscopic world play a role.
- Researchers fabricate mechanical metamaterials with ultra-high energy absorption capacity 27/04/2023 Chinese researchers have successfully fabricated mechanical metamaterials with ultra-high energy absorption capacity using ion track technology. The results were published in Nature Communications as an Editor's Highlight.
- Organometallic boost pushes perovskite solar cells to new record for efficiency and stability 25/04/2023 Adding an organometallic compound to a perovskite solar cell can enhance their efficiency and their stability spectacularly, enabling them to run for 1000 hours with only a minimal drop in performance. The researchers believe the cells can now take the first steps towards commercialisation.
- Team develops the world's smallest and fastest nano-excitonic transistor 20/04/2023 How can Marvel movie character Ant-Man produce such strong energy out of his small body? The secret lies in the transistors on his suit that amplify weak signals for processing. Transistors that amplify electrical signals in the conventional way lose heat energy and limit the speed of signal transfer, which degrades performance. What if it were possible to overcome such limitations and make a high-performance suit that is light and small but without the loss of heat energy?