Articles tagged with Vanadium
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Scientists at The University of Osaka have developed an innovative method for producing NOBIN, a valuable molecule used in pharmaceuticals, by combining a vanadium catalyst and LED light. This clean process yields only water as a byproduct, showcasing exceptional environmental compatibility and waste reduction.
A novel metasurface design using vanadium dioxide enables fast, energy-efficient modulation of terahertz waves. This allows for real-time holographic encryption and decoding, with applications in secure communication, medical imaging, and more.
Researchers developed an electrically tunable metasurface for THz holographic devices, leveraging VO2's reversible transition to minimize energy consumption and response time. The microladder design enables real-time operation, fast switching times, and robust performance.
A new study demonstrates that microscopic differences in iron can be spotted using X-ray fluorescence spectrometry, allowing archaeologists to identify the origin of Spanish iron objects. This technique follows a quiet revolution in southeast archaeology, where metal detectors have been adopted for large-scale survey work.
Researchers from UK and Canada will study ways to reduce mining's environmental footprint and enhance efficiency across critical mineral value chains. The project aims to develop new geological models and exploration tools for rare earth element deposits, aiming to diversify the supply chain and ensure high environmental standards.
Scientists have successfully induced ferromagnetism in pure vanadium oxide by controlling its oxidation states, offering a promising approach to developing advanced magnetic materials. The study demonstrates that by adjusting the oxidation levels of vanadium ions, researchers can engineer ferromagnetic behavior in the material.
Researchers investigate microbial reduction of vanadate to detoxify the environment. Electron transfer pathways, including extracellular and intracellular processes, are identified as crucial for vanadium detoxification. Vanadium isotope fractionation also follows a Rayleigh model, with lighter isotopes reacting preferentially.
A new smart window technology combines liquid crystals with nanoporous microparticles and a patterned vanadium dioxide layer to simultaneously control visible light and infrared radiation. The device offers fast, efficient heat and visibility management, marking a significant step forward in energy-efficient building design.
Researchers have developed a new sodium-ion battery material that improves performance by 15% and increases energy density to 458 Wh/kg. The material, Na x V2(PO4)3, allows for stable operation and continuous voltage change, making it a promising alternative to lithium-ion batteries.
Researchers have found that MXene catalysts are more stable and efficient than metal oxide compounds for the oxygen evolution reaction. The discovery holds promise for developing low-cost, high-performance electrolysers for producing green hydrogen.
Researchers developed a new type of temperature-adaptive radiative cooling device with improved performance, reducing solar absorptance by 7.54% and increasing emissivity by 13.3%. This advancement holds promise for optimizing energy use and advancing sustainable thermal management solutions.
Researchers developed a compact sensor system with infrared imaging capabilities that can be fitted to drones for remote crop monitoring. The system can rapidly switch between edge detection and detailed infrared imaging, allowing farmers to pinpoint specific crop needs and boost harvests.
Scientists at Oregon State University have made a significant advance in capturing carbon dioxide from the air using vanadium peroxide molecules. The technology has been shown to react with and bind carbon dioxide effectively, making it a promising candidate for improving direct air capture methods.
Researchers at Rice University have discovered a new material that exhibits both quantum correlations and geometric frustration, resulting in a unique flat band structure. This finding provides empirical evidence of the effect in a 3D material and has implications for understanding exotic features in materials science.
A computational study conducted by Brazilian researchers found that current density and active species concentration are the main variables affecting capacity loss. The approach successfully mitigated cross-contamination, providing an optimal flow between electrolyte tanks under different operating conditions.
A team of researchers has discovered a way to harness random telegraph noises in semiconductors, generating high-amplitude signals and manifesting inherent quantum states. By introducing vanadium into tungsten diselenide, they created a device that can switch between two stable states using voltage polarity.
Researchers discovered the abundance of rock-forming elements in WASP-76 b's atmosphere, which matches its host star and our own Sun closely. The team found that certain elements are depleted due to temperature conditions, providing insight into the sensitivity of giant planet atmospheres.
Researchers from Osaka University developed a versatile method for preparing heterodimensional superlattices, exhibiting anisotropic electrical conductivity and the anomalous Hall effect at room temperature. This innovation promises to enhance data storage density, lighting efficiency, and electronic device speed.
EPFL researchers have discovered a material called Vanadium Dioxide (VO2) that can remember its previous external stimuli for up to three hours. The material's structural memory is capable of anticipating future events, similar to how neurons in the brain function.
Researchers used a mega-electron-volt ultrafast electron diffraction instrument to study vanadium dioxide's insulator-metal transition. The 'stroboscopic camera' captured the hidden trajectory of atomic motion, showing two stages with non-linear atomic motions in the second stage, influenced by electron orbital forces.
Scientists elucidated the structures at the interface between a working catalyst and reacting molecules in vanadium pentoxide, revealing which oxygen atoms activate hydrocarbons. The study showed that temperature and gas composition influence the reaction, leading to more sustainable oxidation processes.
Scientists developed an all-season smart-roof coating that automatically switches between cooling and heating, outperforming commercial cool-roof systems in energy savings. The technology uses vanadium dioxide to regulate its rate of radiative cooling, overcoming the problem of overcooling in winter.
A new battery-free wearable device detects nicotine in real-time and sends data wirelessly to smartphones, allowing users to measure their exposure to vaporized nicotine. The device uses a thin film of vanadium dioxide to detect conductivity changes caused by nicotine concentration.
Researchers developed a new strategy to characterize polymeric transition metal species in acidic solutions, using ESI-TOF-MS. This method visualized transformation evolutions of vanadium, chromium, tungsten, and molybdenum species, guiding reaction conditions for high-purity metal separation.
Scientists at the Paul Scherrer Institute have developed a new experimental method to investigate the ageing process of vanadium phosphorus oxides (VPO) catalysts. The method allows for precise measurement of chemical properties in three dimensions, revealing changes in the material's structure and chemistry over time.
Researchers create an integrated cathode with 3D porous honeycomb-like CoN-Ni3N/N-C nanosheets, enhancing conductivity and active sites. The resulting supercapacitor achieves remarkable energy density and cycle stability, enabling high-energy-density flexible wearable electronics.
Researchers from Tokyo Metropolitan University have created a new tungsten-substituted vanadium oxide catalyst that works efficiently at 100-150 degrees Celsius, even in wet conditions. The material's superior performance makes it ideal for processing real industrial exhaust and contributing to cleaner air.
A research team at Osaka University developed an ultra-small actuator with unparalleled sensitivity, fast on/off response, and nanometer-scale precision. The actuator uses a phase transition in vanadium oxide crystals to achieve high accuracy and speed, revolutionizing micro-robotics and advanced technologies.
Researchers at Moscow Institute of Physics and Technology uncover the mechanism behind vanadium dioxide films' conductivity, enabling thermal imaging devices with improved performance. The discovery allows for the synthesis of thin films with predefined properties, such as temperature-dependent conductivity.
A hemispherical vanadium oxide cluster cavity can stabilize a polarized Br2 molecule, enabling selective bromination of alkanes. The study reveals different product selectivity compared to the radical mechanism.
A new Duke University study finds that co-occurring contaminants in North Carolina's private wells can heighten health risks for millions of residents. The study highlights the need for more research to better understand the health impacts of geogenic contaminants and mixtures.
A new project at Aarhus University is developing highly efficient and inexpensive components in flow batteries, aiming to disrupt the field of stationary batteries. The goal is to reduce the price further and achieve a levelized-cost-of-electricity-storage below EUR 0.05 per kWh per cycle.
Researchers discovered hydrogen atoms in zirconium vanadium hydride are more tightly spaced than predicted, which could lead to superconductivity at or near room temperature. The team used neutron scattering experiments and computer simulations to understand the phenomenon.
Scientists from Tokyo Metropolitan University developed a low-temperature catalyst using bulk defective vanadium oxide to remove NOx gas from industrial exhaust. The catalyst works at temperatures below 150 degrees Celsius with higher efficiency than conventional catalysts.
Scientists at Princeton University found that vanadium can facilitate nitrogen fixation when molybdenum is scarce, suggesting the process may be more resilient than previously thought. This discovery has significant implications for understanding nutrient budgets and biodiversity in ecosystems.
Researchers at Lehigh University have discovered the mechanism behind a crucial catalyst that reduces harmful industrial emissions. The study found that tungsten oxide changes the structure of vanadium oxide, increasing its activity and reducing undesirable reaction products.
Researchers from NUST MISIS created a unique composite material that can withstand temperatures up to 700°C, outperforming individual components in terms of microhardness. The material's multilayer structure, made possible by high-pressure torsion, enables improved thermal stability and strength.
Researchers developed a novel material inspired by siderophores to selectively bind uranium in seawater, offering an eco-friendly alternative to land-mining. The new adsorbent shows promising performance, increasing storage space for uranium and allowing for recyclable reuse.
Researchers at Rensselaer Polytechnic Institute have developed a new material that improves lithium-ion battery performance, enabling faster charging and higher energy density. The discovery could lead to enhanced applications in consumer electronics, electric vehicles, and solar grid storage.
Scientists at Kanazawa University develop a spherical vanadium oxide cluster that selectively traps carbon dioxide over carbon monoxide. The 'flipped' structure allows for efficient separation of the two gases.
Researchers have successfully developed a new vanadium alloy that is strong at high temperatures and can be used in the manufacturing of the fusion reactor blanket. The alloy, composed of 92% vanadium, has improved ductility due to high purity production methods, making it suitable for welding and machining without breaking.
University of Wisconsin-Madison researchers develop a material that can transition from an insulator to a conductor without changing its atomic structure, enabling faster switching speeds in advanced devices. The breakthrough uses a dual-layer sandwich structure to stabilize the material's unique properties.
Researchers used a new technique to examine the crystal structure of Vanadium Dioxide (VO2) and found that atomic motions during phase transitions are disordered, contradicting previous assumptions. This discovery has significant implications for our understanding of complex materials such as high-temperature superconductors.
Scientists have studied vanadium dioxide's ultrafast phase transition, revealing that atomic motions are unpredictable and occur independently of each other. This discovery lays the groundwork for advances in computer hardware and could lead to breakthroughs in controlling material behavior.
Researchers successfully created the first experimental realization and structural investigation of single-layer VS2, revealing its unique electronic properties. The team discovered a new vanadium sulphide compound with similar stoichiometry to single-layer VS2, raising hopes for two-dimensional magnetism.
Researchers at Texas A&M University have discovered a new type of magnesium-oxide cathode material that promises higher energy density, improved safety, and reduced costs compared to traditional lithium-ion batteries. The breakthrough could enable more efficient and sustainable energy storage for renewable energy sources.
Human emissions of vanadium have spiked since the start of the 21st century due to heavy oil use, surpassing natural sources combined. The health risks of airborne vanadium particles are not well documented but may impair respiratory functions and exacerbate conditions like asthma.
The study found that human activities release significant amounts of vanadium into the environment, primarily through fossil fuel extraction and combustion. The annual global flux of vanadium is dominated by anthropogenic processes, with emissions to the atmosphere estimated to exceed natural emissions by up to 1.7.
Researchers propose using the element vanadium to verify microfossils for signs of life on Mars. Vanadium can substitute into biological compounds and is found in known biological sources, such as chlorophyll.
Researchers at the University of Freiburg have made a significant step towards understanding nitrogenase's function by analyzing its spatial structure. The team discovered that a vanadium ion replaces molybdenum in the enzyme, leading to distinct effects on its geometric and electronic structure.
Researchers at Argonne National Laboratory have developed a vanadium catalyst that enhances the hydrogenation process, previously dominated by expensive precious metals. The breakthrough involves synthesizing vanadium in a unique configuration, demonstrating its catalytic activity.
Scientists have found that electrons in vanadium dioxide move in unison, making it a poor conductor of heat. The material's unique properties make it suitable for applications like thermoelectric systems and window coatings.
Researchers develop a metamaterial device that can blend into its surroundings like a chameleon, using vanadium dioxide to trigger phase changes. The device's ability to change state is tunable by altering the current flowing through it.
Researchers at Penn State have discovered a way to give transistors a power boost by incorporating vanadium oxide into electronic devices. The material's metal-to-insulator transition property can enhance state-of-the-art non-volatile memories and improve the stability and energy efficiency of read, write, and maintain information states.
Researchers at ETH Zurich have discovered a new glass material that can store more energy than traditional lithium-ion batteries. The vanadate-borate glass exhibits improved charging capacity and stability, paving the way for more efficient electric vehicles and longer-lasting portable electronics.
Researchers at Oak Ridge National Laboratory quantify thermodynamic forces driving metal-insulator transition in vanadium dioxide, finding phonons and atomic vibrations control phase stability. The discovery has implications for multifunctional materials, including colossal magnetoresistors, superconductors, and ferroelectrics.
Researchers have successfully observed atomic positions and electron distribution during the transformation of vanadium dioxide from a semiconductor to a metal. This achievement marks the first time that experiments can distinguish between atomic-lattice structure changes and electron relocation at ultrafast speeds.
Researchers created a device that synchronizes two oscillating systems, enabling non-Boolean computing and potentially leading to more efficient information processing. This technology could lead to neuromorphic computer chips using only about one percent of the energy required by digital computers.
A team of scientists from Vanderbilt University has invented an ultra-fast and ultra-small optical switch that can turn on and off trillions of times per second. The device is made of artificial material engineered to have properties not found in nature, breaking the miniaturization barrier for photon-based devices.
Research integrates vanadium dioxide onto a silicon chip to create infrared smart sensors that are faster, more energy-efficient, and lighter than conventional sensors. This breakthrough paves the way for multifunctional spintronic devices with enhanced memory capacity, data transfer speed, and computational power.