Global Energy News (news-and-events/news)

Physicists and biomedical engineers unlocked new properties in capillary waves thanks to superhydrophobicity.

Is it possible to tile a surface with a single shape in such a way that the pattern never repeats itself? In 2022, a mathematical solution to this 'Einstein problem' was discovered for the first time. Researchers have now also found a chemical solution: a molecule that arranges itself into complex, non-repeating patterns on a surface. The resulting aperiodic layer could even exhibit novel physical properties.

When analyzing odorants in food or their raw materials, the formation of artifacts can significantly distort the results. In a new comparative study, researchers have shown that the injection method in gas chromatographic odorant analysis has a decisive influence on the formation of artifacts. On-column injection proved to be the gold standard, while solvent-free methods performed significantly worse.

What if time is not as fixed as we thought? Imagine that instead of flowing in one direction -- from past to future -- time could flow forward or backward due to processes taking place at the quantum level. This is the thought-provoking discovery made by researchers, as a new study reveals that opposing arrows of time can theoretically emerge from certain quantum systems.

Researchers have developed a reactor that pulls carbon dioxide directly from the air and converts it into sustainable fuel, using sunlight as the power source.

Scientists have identified a new property, interface flexibility, that controls how certain molecules naturally self-organize into crystalline supramolecular networks. This significant discovery could change the design of synthetic molecules for network growth at the nanoscale.

Researchers have synthesized a Bi5-ring, a molecule with five bismuth atoms, and stabilized it in a metal complex. Their discovery fills a gap in chemical knowledge and enables future applications in materials research, catalysis, and electronics.

Researchers have made a breakthrough in the development of 'life-like' synthetic materials which are able to move by themselves like worms. Scientists have been investigating a new class of materials called 'active matter', which could be used for various applications from drug delivery to self-healing materials.

Biological motors, which aid microorganism movement in fluids, are composed of two components -- the rotor and stators. Despite much research, the exact molecular mechanism underlying stator function is yet unclear. In a new study, researchers analyzed the flagellar motor in Vibrio alginolyticus using cryo-electron microscopy and described how sodium ion flow through stators underlies stator function. Understanding biological motors better could lead to the development of efficient microscopic machines.

The possibilities for material design and production of plastic components are being expanded through 3D printing technology. However, there is a shortage of recyclable polymers that meet the performance requirements. A research team has now introduced a new class of polymers called polythioenones, which are mechanically and chemically recyclable and suitable for 3D printing. They also demonstrate better mechanical properties than conventional polyolefins -- thanks to a special, ring-shaped building block.

From predicting potholes to designing more durable concrete, artificial intelligence is paving the way for smarter infrastructure, new studies show.

Researchers have quantified the role of the 'hydrogen economy' in making our society more sustainable. They present the results of extensive modelling of pathways to decarbonizing the European economy by 2050. They conclude that when it comes to providing a sustainable primary source of energy, electrification will prove to be the most cost-efficient route for most economic sectors with an average total share of around 60% in final energy consumption. In contrast, the projected share of direct hydrogen use will be 10% at the highest.

Researchers have discovered why LiNiO2 batteries break down, and they are testing a solution that could remove a key barrier to widespread use of the material. The team plans first to manufacture LiNiO2 batteries in the lab and ultimately to work with an industry partner to commercialize the technology.

Researchers have been trying to find new ways to produce and replicate the various useful features observed in nature. Fine hairs and fibers, which are ubiquitous in nature, are useful for various applications ranging from sensory hairs to the fibers that give hagfish slime its unique consistency.

Electronic textiles, such as heating pads and electric blankets, can keep the wearer warm and help ease aches and pains. However, prolonged use of these devices could possibly cause heat-related illnesses, including hyperthermia or burns. Recently, a group of researchers designed and tested a 'smart' jacket equipped with environmental sensors, heat-generating and color-changing yarns, and artificial intelligence (AI) to control temperature and prevent overheating.

A new version of Cellpose -- the popular tool that maps the boundaries of diverse cells in microscopy images -- now works on less-than-perfect pictures that are noisy, blurry, or undersampled.

A biohybrid hand which can move objects and do a scissor gesture has been created. The researchers used thin strings of lab-grown muscle tissue bundled into sushilike rolls to give the fingers enough strength to contract. These multiple muscle tissue actuators (MuMuTAs), created by the researchers, are a major development towards building larger biohybrid limbs. While currently limited to the lab environment, MuMuTAs have the potential to advance future biohybrid prosthetics, aid drug testing on muscle tissue and broaden the potential of biohybrid robotics to mimic real-life forms.

Researchers have achieved a breakthrough in wearable health technology by developing a novel self-healing electronic skin (E-Skin) that repairs itself in seconds after damage. This could potentially transform the landscape of personal health monitoring.

A new study has revealed the clearest-ever picture of the surface chemistry of worm species that provides groundbreaking insights into how animals interact with their environment and each other. These discoveries could pave the way for strategies to deepen our understanding of evolutionary adaptations, refine behavioural research, and ultimately overcome parasitic infections.

Scientists have demonstrated that negative refraction can be achieved using atomic arrays -- without the need for artificially manufactured metamaterials. Scientists have long sought to control light in ways that appear to defy the laws of Nature. Negative refraction -- a phenomenon where light bends in the opposite direction to its usual behavior -- has captivated researchers for its potential to revolutionize optics, enabling transformative technologies such as superlenses and cloaking devices. Now, carefully arranged arrays of atoms have brought these possibilities a step closer, achieving negative refraction without the need for artificially manufactured metamaterials.