Showing Spotlights 49 - 56 of 2226 in category All (newest first):
Due to their excellent electron-transport properties and extremely high carrier mobility, graphene and other other direct bandgap monolayer materials such as transition-metal dichalcogenides (TMDCs) and black phosphorus show great potential to be used for low-cost, flexible, and highly efficient photovoltaic devices. A recent review provides a comprehensive overview on the current state-of-the-art of 2D-materials-based solar photovoltaics. It describes the recent progress made with graphene, graphene-based materials, and other 2D materials for solar photovoltaics, including silicon-based solar cells, and organic and perovskite solar cells.
Jan 7th, 2019
For the first time, researchers have successfully developed a new version of phase-change memory that reduces the switching time and allows memory cells to produce excellent stability.
The new type of phase-change memory can be as fast as state-of-the-art RAM chips being considered to power artificial intelligence (AI) in phones, and it could also be used to power a range of other smart devices. The new version of phase-change memory could be manufactured with a cheap process: The procedure uses a normal voltage pulse and requires no additional special materials.
Dec 31st, 2018
Motivated by the outstanding performance of graphene, graphene-like 2D materials have been intensively investigated, such as topological insulators, transition metal dichalcogenides (TMDs) and black phosphorous. Recently, 2D titanium disulfide, a typical TMD, is found to have strong light absorption properties from visible to infrared region, which is highly attractive for applications in nonlinear photonics. Researchers have fabricated a novel saturable absorber device is successfully fabricated based on 2D TiS2 nanosheets for ultrashort pulse generation and all-optical thresholding at the communication band.
Dec 27th, 2018
Due to the unique physical and chemical characteristics, such as good electrical conductivity, low weight, large surface areas, high electrochemical activity, and facile doping of heteroatoms or inorganic species, there are increasing demands of fabricating two-dimensional (2D) porous carbon for lithium-ion batteries, supercapacitors, electrochemical catalysts and many other emerged applications in energy storage and conversion. Researchers now have developed a fast, scalable, and eco-friendly active-salt-templating strategy to engineer different types of 2D porous carbons.
Dec 21st, 2018
Nanoparticles that mimic the complexity and function of natural enzymes can act as effective peroxidase to catalyse for the oxidization of 3,3,5,5-tetramethylbenzidine (TMB), generating an oxidised blue-coloured product. For the first time scientists found that when the surface of gold nanoparticle (AuNPs) is coated with casein, the intrinsic peroxidase-mimicking activity of AuNPs is suppressed strongly, i.e. by up to 77.1%, due to the surface shielding effects.
Dec 6th, 2018
The idea has been around for a while that selected segments of RNA or DNA could be used therapeutically to affect gene or cell function. The attraction for researchers is the flexibility that these therapeutic nucleic acids' (TNAs) versatility, programmability, and modularity affords them and shows a promising route towards treatment for a wide variety of disorders such as cancer, metabolic disorders, viral infections, cardiovascular and inflammatory diseases. Due to the programmability of RNA and DNA, scientists now are able to embed functional assemblies with controllable immunogenic potential into nucleic acid-based nanoparticles to eliminate the immune response and control the timing of their therapeutic activation.
Dec 5th, 2018
One of the most pervasive reliability problems facing the computer chip industry is ESD (electrostatic discharging) failure caused by the rapid, spontaneous transfer of electrostatic charge induced by a high electrostatic field. A novel above-IC graphene based nanoelectromechanical system (NEMS) switch structure for on-chip ESD protection utilizes the unique properties of graphene. This switch is a two-terminal device with a vacuum gap between a conducting substrate at the bottom and a suspended graphene membrane on top serving as the discharging path.
Dec 4th, 2018
Over the past several years, metal nanoparticles photosensitization over semiconductors with a large band gap has emerged as a promising strategy for developing visible-light responsive photocatalytic materials. In new work, researchers demonstrate a new plasmonic metamaterial can absorb nearly 100% of incident light (of a specific color) and use this energy to accelerate the production of chemicals. In constructing the near-perfect absorber, the researchers employ gold nanoparticles, TiO2 as the spacer layer, and a continuous gold thin film as the rear reflective layer.
Nov 28th, 2018