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Category: chemistry – Page 52

This Groundbreaking Hydrogel Generates Hydrogen and Oxygen via Artificial Photosynthesis (Using Water and Light)

In a major leap toward sustainable energy, a team of Japanese researchers has developed an artificial photosynthesis system that could help generate hydrogen and oxygen from just water and light. The breakthrough is thanks to a new type of hydrogel, which mimics the natural process of photosynthesis and performs these reactions without requiring external energy. This innovation opens up exciting possibilities for clean energy production, potentially transforming the way we think about renewable resources.

Artificial photosynthesis has long been a goal for scientists looking to replicate the natural process plants use to convert light into energy. The concept is simple in theory: use light to drive chemical reactions that produce useful energy, such as hydrogen. However, previous attempts to harness this process have been hampered by the need for external energy to trigger the reactions, making the systems inefficient and difficult to scale.

Enter hydrogels —a promising new solution. These polymer-based materials are capable of responding to external stimuli like temperature, light, and pH. The challenge, however, has been that these materials often suffer from self-aggregation, where the molecules clump together and hinder the energy conversion process. The Japanese researchers, however, have overcome this obstacle by designing a hydrogel that maintains the precise arrangement of its molecules, enabling a more effective energy transfer.

Artificial organic neuron closely mimics the characteristics of biological nerve cells

Researchers at Linköping University (LiU), Sweden, have created an artificial organic neuron that closely mimics the characteristics of biological nerve cells. This artificial neuron can stimulate natural nerves, making it a promising technology for various medical treatments in the future.

Work to develop increasingly functional artificial continues at the Laboratory for Organic Electronics, LOE. In 2022, a team of scientists led by associate professor Simone Fabiano demonstrated how an artificial organic neuron could be integrated into a living carnivorous plant to control the opening and closing of its maw. This synthetic nerve cell met two of the 20 characteristics that differentiate it from a biological nerve cell.

In their latest study, published in the journal Nature Materials, the same researchers at LiU have developed a new artificial nerve cell called conductance-based organic electrochemical neuron, or c-OECN, which closely mimics 15 out of the 20 neural features that characterize biological nerve cells, making its functioning much more similar to natural nerve cells.

Synthetic neurons that mimic human processes could lead to smarter robotics

Artificially engineered biological processes, such as perception systems, remain an elusive target for organic electronics experts due to the reliance of human senses on an adaptive network of sensory neurons, which communicate by firing in response to environmental stimuli.

A new collaboration between Northwestern University and Georgia Tech has unlocked new potential for the field by creating a novel high-performance organic electrochemical neuron (OECN) that responds within the frequency range of human neurons. The team also built a complete perception system by designing other organic materials and integrating their engineered neurons with artificial touch receptors and synapses, which enabled real-time tactile signal sensing and processing.

The research, described in a paper in Proceedings of the National Academy of Sciences, could move the needle on intelligent robots and other systems currently stymied by sensing systems that are less powerful than those of a human.

Scientists Discover Key Brain Mechanism Behind Anorexia

New research found that individuals with anorexia nervosa have elevated opioid neurotransmitter.

A neurotransmitter is a chemical substance that transmits signals across a synapse from one neuron to another in the nervous system. These chemicals play a crucial role in the functioning of the brain and body, influencing everything from mood, sleep, and learning to heart rate, anxiety, and fear. Common neurotransmitters include dopamine, serotonin, acetylcholine, and norepinephrine. They bind to specific receptors on the surface of neurons, triggering various physiological responses and allowing for the communication that underpins all neural activities. Imbalances in neurotransmitter levels can lead to neurological disorders or mental health issues, making them a central focus of study in both medicine and psychology.

Quantum Computing’s Biggest Obstacle Just Got Solved — Thanks to Self-Assembling Qubits

However, a new study proves that hydrogen bonds can effectively link spin centers, enabling easier assembly of molecular spin qubits. This discovery could transform quantum material development by leveraging supramolecular chemistry.

A Light-Driven Approach to Spin Qubits

Qubits are the fundamental units of information in quantum technology. A key challenge in developing practical quantum applications is determining what materials these qubits should be made of. Molecular spin qubits are particularly promising for molecular spintronics, especially in quantum sensing. In these systems, light can stimulate certain materials, creating a second spin center and triggering a light-induced quartet state.

Researchers Unveil How Our Brains Decode Space and Time

A study by cognitive neuroscientists at SISSA investigated how the human brain processes space and time, uncovering that these two types of information are only partially connected.

Imagine a swarm of fireflies flickering in the night. How does the human brain process and integrate information about both their duration and spatial position to form a coherent visual experience? This question was the focus of research by Valeria Centanino, Gianfranco Fortunato, and Domenica Bueti from SISSA’s Cognitive Neuroscience group, published in Nature Communications

<em> Nature Communications </em> is an open-access, peer-reviewed journal that publishes high-quality research from all areas of the natural sciences, including physics, chemistry, Earth sciences, and biology. The journal is part of the Nature Publishing Group and was launched in 2010. “Nature Communications” aims to facilitate the rapid dissemination of important research findings and to foster multidisciplinary collaboration and communication among scientists.

‘Eternal’ 5D memory crystal capable of storing 360 TB of data for billions of years now holds a full human genome

The data inscribed into the crystal is carefully annotated with universal elements like hydrogen, oxygen, carbon, and nitrogen, as well as the four DNA bases—adenine, cytosine, guanine, and thymine—that make up the genetic code. Additionally, the molecular structure of DNA and the arrangement of genes within chromosomes are depicted, offering clear instructions on how to interpret the genetic information stored within.

However, it is important to note that the 5D memory crystals require a highly specialized skill set and advanced equipment to inscribe and read the data stored within the crystals, so those looking to re-establish the human race after an extinction event may have to refer to more traditional means.

The crystal, made from fused quartz, is one of the most chemically and thermally resilient materials known on Earth, and can endure temperatures as high as 1000°C, resist direct impact forces up to 10 tons per square centimeter, and is unaffected by long-term exposure to cosmic radiation. The longevity and storage capacity of the 5D memory crystal earned it a Guinness World Record in 2014 for being the most durable data storage material ever created.

MIT engineers develop breakthrough technology that could change the way we process metal: ‘This is a huge advantage’

According to management consulting firm BCG, only around half of all aluminum beverage cans are recycled in the United States, which is far behind countries such as Germany. What’s more, aluminum has one of the highest recycling rates in the U.S. — only around 19% of the durable goods sold in the U.S. are recycled, including only 14% of plastic containers and packaging. The rest is sent to landfills, where it leaches toxic chemicals into the surrounding soil and waterways.

New processes such as the one developed by the MIT researchers can hopefully make a difference in those numbers.

“We’re not just preventing waste,” said John H. Lienhard, another one of the researchers. “This membrane technology also enables a circular economy for aluminum, which could reduce the need for new mining and help mitigate some of the industry’s environmental footprint.”

New avenues in quantum research: Supramolecular chemistry detects qubit candidates

A Franco-German research team, including members from the University of Freiburg, shows that supramolecular chemistry enables efficient spin communication through hydrogen bonds. The work is published in the journal Nature Chemistry.

Qubits are the basic building blocks of information processing in quantum technology. An important research question is what material they will actually consist of in technical applications. Molecular spin qubits are considered promising qubit candidates for molecular spintronics, in particular for quantum sensing. The materials studied here can be stimulated by light; this creates a second spin center and, subsequently, a light-induced quartet state.

Until now, research has assumed that the interaction between two spin centers can only be strong enough for successful quartet formation if the centers are covalently linked. Due to the high effort required to synthesize covalently bonded networks of such systems, their use in application-related developments in the field of quantum technology is severely limited.