Articles tagged with Polymers
Researchers have developed self-assembled energetic coordination polymers based on multidentate pentazole cyclo-N5-, which exhibit high energy density and detonation performance. The polymers outperform existing materials like TNT, RDX, HMX, and CL-20.
Researchers have developed a magnetic treatment to isolate and remove unwanted substances in cabernet sauvignon wine. This technique, using polymers with magnetic nanoparticles, shows promise in removing off-tasting compounds without altering the desired flavors.
Researchers at Université libre de Bruxelles estimate nanoconfinement impacts material contacts, interfacial interactions and vdW forces. Thinner films exhibit reduced contacts with silicon wafers due to weaker van der Waals forces.
Researchers used machine learning to automate the search for well-matched solar materials, creating a new organic photovoltaic polymer. The study suggests that AI could accelerate solar cell development by instantaneously predicting results and providing crucial support for molecular designers.
A new study by Maziar Heidari and colleagues introduces an adaptive resolution simulation technique that couples accurate models with simpler, idealized representations of solids. This approach enables efficient computation of thermodynamic properties at a reduced computational cost.
Researchers at Penn State developed a new composite material that can efficiently harvest mechanical and thermal energy using a 3D piezoelectric ceramic foam supported by a flexible polymer. The material outperforms traditional piezoelectric composites, offering improved flexibility and energy output.
A new nanoparticle vaccine developed by MIT researchers can deliver multiple doses of the polio vaccine in just one injection, making it easier to immunize children in remote regions. The vaccine uses a biodegradable polymer that releases the vaccine in bursts at defined time points, providing long-lasting immunity.
Researchers have developed a forming technology that allows for the structuring of quartz glass like a polymer, opening up new opportunities for the glass processing industry and various fields such as optics, data technology, and medical engineering. The process involves mixing small glass particles with a liquid polymer and then hard...
Engineers at Caltech and ETH Zurich developed self-propelled robots that paddle through water using temperature-responsive materials. The devices use a bistable element and polymer strips to activate a switch and propel forward.
Researchers propose a new method for orienting liquid crystals, increasing viewing angles in LCD displays. The technique uses liquid-crystal polymers with varying side-chain lengths to control orientation.
Researchers at TU Dresden are developing intelligent material combinations for autarkic fibre composites with integrated actuators and sensors. These materials can react quickly and precisely to environmental changes, making them suitable for applications in mechanical engineering, robotics, architecture, and orthotics.
Self-assembled block polymer membranes offer customizable pore sizes and can selectively remove contaminants from various water sources. The technology has the potential to advance water treatment technologies, enabling decentralized reuse of wastewater and reducing chemical demands for membrane cleaning.
A UH engineer is working to understand how crystals form in soft materials, with potential applications in drug design, biomedical diagnostics and petrochemical production. The researcher aims to control the crystallization process to improve outcomes in various fields.
Scientists have developed a method to modify graphene without destroying it, creating a stable structure called 'polymer carpets'. When exposed to light, these carpets generate current, making them suitable for use in solar batteries and flexible electronics.
Researchers develop a model that explains how microtubule lengths are regulated by motor proteins and resources. The study found that when resources are limited, microtubules can exhibit bistability, resulting in two distinct lengths, which is relevant to cell migration and division.
Researchers at Ruhr-University Bochum have developed a new catalyst with a self-defense mechanism against oxygen damage, using DuBois-type complexes based on abundant metals. The protection system involves an immobilization matrix that electrically disconnects the catalyst from the electrode surface.
A team of researchers led by NYU Tandon Professor André D. Taylor has found an innovative way to improve solar cells, making them more efficient and suitable for various applications. The new material 'sandwich' combines different materials to absorb sunlight and transform it into electricity.
Researchers developed a rapid and efficient way to wrap liquid droplets in ultrathin polymer sheets, reducing the time from minutes to seconds. The technique exploits the dynamics of droplet impact and demonstrates robust results for various shapes and fluid combinations.
Researchers have created a composite material with the best piezoelectric properties today, overcoming lead content and weight limitations. The material's polymer component offers advantages in manufacturing and application, making it suitable for high-pressure sensing applications.
Researchers develop polymers that can change colors like structural color in nature, enabling smart decorations and anti-counterfeiting measures. The new materials use inkjet printing technology to produce a wide range of colors, including blue, green, orange, and red.
Researchers developed stable, self-disrupting microbubbles to carry oxygen in the blood, reducing the risk of embolism. The microbubbles were shown to increase survival rates in rodents with cardiac arrest, providing a potential lifesaving treatment.
Researchers at Kyushu University have developed a novel electrolytic flow cell that can produce glycolic acid (GC) from oxalic acid, offering a promising solution for energy storage. The device uses a polymer membrane and porous TiO2 catalyst to achieve high efficiency and capacity.
Dr. Yu Zhu's team developed a new polymer binding material and process to improve battery cyclability and storage density, extending the time between charges and overall battery life.
Scientists have created asymmetrical polymer structures that bind together in a spatially defined manner, similar to atoms coming together to make molecules. This breakthrough technique could lead to new materials for applications ranging from drug delivery to 'soft robotics',
Scientists develop mathematical model to explain co-nonsolvency phenomenon, which was previously unknown. The model predicts polymer behavior in mixed solvents and reveals mechanism for suppressing co-nonsolvency at high pressures.
Researchers at UMass Amherst developed a polymer-based system storing more than two times higher energy density than previous systems. The new technology has potential applications in solar-powered heating and could provide sustainable energy storage for areas without access to power grids.
A study found that concentration fluctuations are enhanced by thermal convection in mixtures of high and low viscosity liquids. Immobile regions are also formed during this process due to the large viscosity difference.
Researchers discovered that polyelectrolyte brush bristles collapse due to the addition of powerful electrolytes but can be restored with gentler ions. This study increases understanding of these chemical brushes, which have potential applications in medicine and industry, including lubrication and medical devices.
Researchers at OIST created a device to study small-scale whirlpools and found that adding polymers reduces vortex intensity, saving energy. The discovery has implications for optimizing flows in lab-on-a-chip devices and improving inkjet printer resolution.
Researchers at Brigham and Women's Hospital have developed a novel surgical adhesive inspired by the elastic defensive slime of the Dusky Arion slug. The new sealant mediates strong interfacial contact, conforms to skin and tissue, and closes holes in heart tissue with high effectiveness.
Researchers at Johannes Gutenberg University Mainz have developed a novel synthesis strategy for highly reactive substances, overcoming the formation of polymers through electrochemical polymerization. This method uses an environmentally friendly approach with minimal reagent waste and produces only hydrogen as byproduct.
A Polish Academy of Sciences team has developed a polymer 'love hormone' sensor that can detect micromolar concentrations of oxytocin, a biomarker associated with autism. The sensor's sensitivity is expected to increase to nanomolar levels, allowing for early diagnosis and potentially dramatic treatment efficacy improvements.
Researchers at KAUST developed a solvent-free synthesis method for metal-sulfide nanoparticles using thiourea. The new method produces controllable composition and size of nanoparticles, with potential applications in electrical, optical, and chemical devices.
Researchers have developed a new method using synthetic DNA aptamers to measure cocaine's effect on the brain in real-time with high resolution. The study aims to answer whether age-related differences are due to neuron sensitivity or drug concentration in specific brain areas.
Researchers at the University of Pennsylvania have developed filters that use nanoparticles to prevent biofilm buildup, increasing efficiency and lifespan. The new membranes block bacteria- and virus-sized contaminants without letting them stick.
Researchers created a polymer-based material with enhanced strength and elasticity by mimicking a mussel's adhesive qualities. The material, which is 770 times stiffer and 92 times tougher than its untreated precursor, offers potential applications in structural, biomedical, and aerospace materials.
Physicists Pendar Mahmoudi and Mark Matsen found a simple mathematical formula to describe the interfacial tension between immiscible short- and long-chain polymers. The molecular weight affects segregation levels, leading to universal dependences on polymer distribution.
Researchers at ETH Zurich have created biocompatible microsensors made from magnesium wire and compostable polymer for temperature measurement in food products. The sensors are thin, flexible, and can function for up to 67 days before dissolving, making them suitable for monitoring fish shipments.
Researchers at IBS Institute for Basic Science observed polymers in liquid inside graphene pockets without staining, revealing their dynamic movement. The study paves the way for observing life's building blocks and self-assembly of materials.
Researchers at Nagoya Institute of Technology developed a metal-free method to control cationic polymerization using halogen bonding and ammonium salt additives. The new process produces long, homogeneous polymers suitable for industrial applications.
Researchers create novel microparticles that can deliver multiple doses of a drug or vaccine with just one injection, using a biocompatible polymer and custom-built 3D printing method. The particles release drugs or vaccines at specific time intervals, mimicking the way a series of vaccines would be given, potentially improving patient...
Dissolvable electronics can be triggered to dissolve by ambient moisture, offering a new way to make environmentally friendly devices and biomedical implants. Researchers have developed a model that controls the dissolution kinetics of functional devices, allowing for precise control over the transient period.
Researchers at Université libre de Bruxelles found that molecules move faster as they approach adhesive surfaces due to the nanoconfinement effect. However, this increased movement rate is only temporary, lasting until new molecules fill in the gaps and slow down the molecular movement.
Japanese researchers investigated the effects of charged group spacer length on hydration state in polymer brushes, revealing a clearer picture of the relationship between structure and properties. The results show that hydration states are independent of chain spacer length, with water uptake not affected by this parameter.
Researchers have developed a mussel-inspired glue that can prevent premature labor and promote healthier futures for babies. The adhesive, infused with dihydroxyphenylalanine from mussel feet, has shown promise in preventing amniotic sac tears during fetal surgery.
Researchers have synthesized new liquid-crystal photochromic polymers with comb-shaped molecules that change molecular orientation under external fields, forming coatings and films. These polymers exhibit photoisomerization and photo-orientation processes, allowing for control over phase behavior and optical properties.
A lubricant-infused polymer coating has been developed to prevent mussel fouling, a significant problem in marine environments. The coating tricks mussels into not producing their adhesive threads, reducing the problem of fouling on ship hulls and marine pipes.
Researchers at the University of Bonn have created exotic quantum states made from light by creating an optical 'well' that traps a super-photon. This achievement marks a significant step towards developing quantum circuits and improving quantum communication and computing capabilities.
A new composite material made from a combination of polymers and hexagonal boron nitride nanosheets has been developed by Penn State researchers. This material can store energy at operating temperatures above 176 degrees Fahrenheit, outperforming current commercial polymers.
Researchers have developed a new type of adhesive substance that mimics the properties of slug mucus, effectively sealing wounds after surgery. The substance was found to be strong, flexible and non-toxic, with performance comparable to using a hemostat in emergency surgical procedures.
Scientists at the University of Chicago have discovered a new way to precisely pattern nanomaterials, enabling the creation of complex structures and paving the way for next-generation electronics. The DOLFIN technology makes it possible to mass-produce nanomaterials directly into usable devices.
Researchers have gained new insights into the arrangement of stiff polymers in spherical cavities using computer simulations. The study reveals complex structures emerging on the sphere surface, including bipolar patterns and a tennis ball-like structure with four distinct poles.
A KAIST research team developed molecular pulley binders for high-capacity silicon anodes in lithium ion batteries, improving charge-discharge cycles. The innovative binding system, inspired by the 'mechanical bond' concept, enhances electrode stability and capacity retention.
Scientists at Eindhoven University of Technology developed a new material that can undulate and propel itself forward under the influence of light. The device, the size of a paperclip, is the world's first machine to convert light directly into walking using one fixed light source.
Researchers have developed a novel material that rapidly removes perfluorooctanoic acid (PFOA) from water, achieving concentrations below 10 parts per trillion. The material, made from a networked polymer, has shown greater affinity for PFOA than activated carbon and can be regenerated multiple times.
A synthetic sensor array, resembling an artificial tongue, can detect closely related whisky samples as distinct. The device identifies key qualities such as malt status, age, and country of origin, making it a valuable tool for spotting counterfeits.
Researchers from Kyoto University, Imperial College, and City University of Hong Kong have developed mixed matrix membranes that can capture and store carbon dioxide efficiently and cost-effectively. The new materials have the potential to reduce large project costs by up to tenfold, making CCS technology more politically acceptable.
Researchers at Ben-Gurion University have developed a new biomedical polymer that targets damaged tissue, reducing existing plaque and preventing further progression and inflammation. The therapy has shown promising results in mice, improving myocardial function, decreasing inflammation, and thinning arteries.
Researchers developed a novel approach to create self-expandable polymer stents that can grow with pediatric patients, are biodegradable, and require minimally-invasive procedures. The stents were created using computational design, simulation tools, and 3D printing technology.
Researchers at KAUST have developed a strategy to create highly fluorescent nanoparticles through molecular design of conjugated polymers. The twisted shape of the molecules produces smaller, brighter particles with tunable spectroscopic properties, opening up new opportunities for bio-imaging and nanomedicine.