Molecular 'velcro': Covalent bonds between 2D materials unlock enhanced optoelectronic capabilities

Researchers have chemically linked 2D materials using a molecular "velcro," resulting in a device with improved optoelectronic properties. The device, made of palladium nanosheets covalently bonded with MoS2, shows an enhanced optoelectronic response in the infrared thanks to the chemically bonded interface between the two materials, in comparison to its van der Waals counterpart. This next generation of 2D-2D heterostructures goes beyond van der Waals thanks to the strong covalent bonds between its 2D materials.

phys.org > Nanomaterials

DNA nanorobots that can alter artificial cells offer a new tool for synthetic biology

The shape and morphology of a cell play a key role in the biological function. This corresponds to the principle of "form follows function," which is common in modern fields of design and architecture. The transfer of this principle to artificial cells is a challenge in synthetic biology. Advances in DNA nanotechnology now offer promising solutions. They allow the creation of novel transport channels that are large enough to facilitate the passage of therapeutic proteins across cell membranes.

phys.org > Nanomaterials

Versatile nanothermometer enables real-time material structure and temperature observation

Technological advancements in the simultaneous observation of ultrafine structures and temperature changes in materials are paving the way for the development of advanced materials. This innovation is expected to facilitate the analysis of the correlation between specific structures and the thermodynamic properties of samples.

phys.org > Nanomaterials

Micro, modular, mobile—DNA-linked microrobots offer new possibilities in medicine and manufacturing

When robots are made out of modular units, their size, shape, and functionality can be modified to perform any number of tasks. At the microscale, modular robots could enable applications like targeted drug delivery and autonomous micromanufacturing; but building hundreds of identical robots the size of a red blood cell has its challenges.

phys.org > Nanomaterials

Sustainable nanofiber coating can extend fruit shelf life

As fruits and vegetables are perishable, it can be challenging to keep them fresh and safe to eat. In the time it takes to transport them from farm to table, these difficulties with post-harvest storage mean that enormous amounts of fresh produce are currently being wasted. While this waste can be reduced with the help of cold storage and robust packaging, these solutions are often highly unsustainable. They involve non-biodegradable plastics, or harmful chemicals which can leach into food and soil damaging the environment and even our own health.

phys.org > Nanomaterials

Combining graphene and nanodiamonds for better microplasma devices

Microplasma devices are incredibly versatile tools for generating and sustaining plasmas on micro- and millimeter scales. The latest advances in nanotechnology now promise to expand their range of applications even further but, so far, this progress has been held back by the limited stability of some nanostructures at the extreme temperatures required to sustain many plasmas.

phys.org > Nanomaterials

Discovery of bistable nanocrystals promises faster, more energy-efficient optical computing

Scientists, including an Oregon State University chemistry researcher, have taken a key step toward faster, more energy-efficient artificial intelligence, and data processing in general, with the discovery of luminescent nanocrystals that can be quickly toggled from light to dark and back again.

phys.org > Nanomaterials

Diversifying DNA origami: Generative design tool relies on grammar rules for finding best shape

Just as the name suggests, DNA origami is a fabrication technique wherein researchers fold DNA strands to create precisely shaped 2- and 3-dimensional nanostructures. These highly programmable structures have the potential to transform drug delivery, diagnostic medicine, nanomaterials formation and molecular computing, but much like crafting paper origami, scientists are limited to the designs they can conceptualize.

phys.org > Nanomaterials

New 'all-optical' nanoscale sensors of force access previously unreachable environments

Mechanical force is an essential feature for many physical and biological processes. Remote measurement of mechanical signals with high sensitivity and spatial resolution is needed for a wide range of applications, from robotics to cellular biophysics and medicine and even to space travel. Nanoscale luminescent force sensors excel at measuring piconewton forces, while larger sensors have proven powerful in probing micronewton forces.

phys.org > Nanomaterials

Engineers develop first deep-UV microLED display chips for maskless photolithography

In a breakthrough set to revolutionize the semiconductor industry, the School of Engineering of the Hong Kong University of Science and Technology (HKUST) has developed the world's first-of-its-kind deep-ultraviolet (UVC) microLED display array for lithography machines. This enhanced efficiency UVC microLED has showcased the viability of a lowered cost maskless photolithography through the provision of adequate light output power density, enabling exposure of photoresist films in a shorter time.

phys.org > Nanomaterials

2D materials with 'twist' show unexpected electronic behavior that defy theoretical predictions

In the search for new materials that can enable more efficient electronics, scientists are exploring so-called 2D materials. These are sheets of just one atom thick, that may have all kinds of interesting electronic properties. If two sheets are placed on top of each other at specific angles, this may lead to new properties such as superconductivity. University of Groningen materials scientist Antonija Grubišić-Čabo and her colleagues studied such a "twisted" material and discovered that it defied theoretical predictions.

phys.org > Nanomaterials

Light-driven method creates molecular fit that would otherwise be impossible

Exploiting an ingenious combination of photochemical (i.e., light-induced) reactions and self-assembly processes, a team led by Prof. Alberto Credi of the University of Bologna has succeeded in inserting a filiform molecule into the cavity of a ring-shaped molecule, according to a high-energy geometry that is not possible at thermodynamic equilibrium. In other words, light makes it possible to create a molecular "fit" that would otherwise be inaccessible.

phys.org > Nanomaterials