Tag: nanoscale

Ultra-compact AI chip operating at speed of light Australian researchers have built an ultra-compact artificial intelligence (AI) chip that is able to make calculations using the power of light, at ...

Exploring materials at the atomic scale Exploring materials at the atomic scale: The X-ray diffraction and imaging facility at MIT.nano adds a new tool to support research in a wide ...

Reshaping gold leads to new electronic and optical properties By changing the physical structure of gold at the nanoscale, researchers can drastically change how the material interacts with light – ...

Researchers crack the code of body’s ancient immune defense A collaborative team from Penn Medicine and Penn Engineering have  unraveled the mathematics of a 500-million-year-old protein network that ‘decides’ which ...

Metal fleece: material for the batteries of the future Battery electrodes thicken as a result of the accelerated transport of lithium ions via metal fleeces, making them particularly efficient and ...

Depositing dots on corrugated chips improves photodetector capabilities Near-infrared photodetectors are used in biomedical sensing and defense and security technologies. For enhanced performance and integrated, compact imaging systems, the photodetectors ...

Improving Rapid Tests: DNA Nanotechnology Boosts Sensitivity of Test Strips An LMU research team has significantly improved conventional test strips by building a nanoscale amplifier from DNA origami. This allows ...

Researchers develop new design and fabrication method to make lightsails for interstellar travel In a potential step toward sending small spacecraft to the stars, researchers have developed an ultra-thin, ultra-reflective ...

Diamonds are Forever But Not in Nanodevices Ultrawide-bandgap semiconductors—such as diamond—are promising for next-generation electronics due to a larger energy gap between the valence and conduction bands, allowing them to ...

Energy-Efficient Microelectronics Discovered: Fabric fortified by light beats might be jump toward more energy-efficient supercomputing. Ferroelectric fabric adjusts to light jolts by reorganizing nuclear network on the nanoscale. Researchers have ...