Articles tagged with Fluids
Scientists at Chung-Ang University have pioneered a novel method for controlling microdroplet motion on solid surfaces using near-infrared light. This approach allows for more precise control than traditional thermal techniques and opens up new possibilities for applications in microfluidics, drug delivery, and self-cleaning surfaces.
Scientists have found that axisymmetric 'spike waves' can exceed previously thought limits on ocean wave height, leading to significant implications for maritime safety. The new research revealed the fundamental mechanisms behind highly directional and crossing waves becoming much larger than others.
A new study found that microgravity analog culture profoundly affects the microbial infection process in 3-D human tissue models. This is critical for ensuring astronaut health on extended space missions and sheds light on mysterious processes of infection on Earth.
Cornell researchers have designed a micro-sized artificial cilial system using platinum-based components that can control the movement of fluids at a scale similar to biological cilia. The technology could enable low-cost diagnostic devices for testing blood samples, manipulating cells or assisting in microfabrication processes.
A new method called sensPIV has been developed to measure both flow and oxygen concentrations simultaneously at the smallest scales. This breakthrough allows researchers to study how corals generate flows, increasing oxygen transport, and has potential applications in life sciences, microfluidics, and medicine.
Researchers conducted wave-optics simulations to study the impact of turbulence on light beams, finding that branch point density grows non-linearly with grid resolution. The study's results could lead to more accurate modeling and improved performance in Adaptive Optics systems.
A team of researchers has developed a novel method using infrared imaging to assess glymphatic function, which is crucial for understanding neurological conditions. The technique allows for the measurement of temporal dynamics of glymphatic functions and provides insights into brain fluid exchange and clearance.
Scientists from the University of Geneva discover that copper deposits are formed by mechanisms similar to those causing large volcanic eruptions. The 'porphyry' deposits, containing copper, form when hot fluids release from cooling magmas and develop under the earth's surface.
Researchers developed a soft robotic sleeve controlled with a microfluidic chip that reduces treatment cost, weight, and power consumption for lymphedema treatment. The device promotes fluid flow in the lymphatic system by sequentially inflating balloons and pushing fluid upwards.
A team of scientists successfully controlled multistep enzyme reactions using audible sound, creating a new method for spatiotemporal regulation. The researchers used standing waves generated by sound to separate and compartmentalize solutions, allowing for the precise control of chemical reactions.
Researchers from Skoltech and others develop a simplified method using polarized light to identify icy areas on aircraft plating. This enables lab assistants to accurately measure the time it takes for ice to form, reducing the risk of accidents by up to 90%.
Researchers develop new procedure to study microorganisms in shallow-water hydrothermal systems, using incubators on the sea floor to study dynamic communities. They reveal key roles in carbon fixation and adaptation under changing conditions.
Researchers subject Oreos to various tests, finding that the cream almost always separates onto one wafer, regardless of flavor or amount of filling. The team's study provides insights into the properties of yield stress fluids and offers a new approach to understanding non-Newtonian materials.
A new study using subsurface imaging sheds light on the geological connection between Yellowstone's iconic hydrothermal features and deeper heat sources. The research team detected hydrothermal alteration and found a remarkable similarity in deep structure beneath areas such as Norris Geyser Basin and Lower Geyser Basin.
Researchers at UBCO's School of Engineering have developed a new, faster method for analyzing toxic waste materials using fluorescence spectroscopy and convolutional neural networks. This method can detect key toxins such as naphthenic acids in oil sands samples, providing a low-cost alternative to current methods.
Researchers found that polymer molecules interact with the flow around gas bubbles, causing a sudden increase in velocity. This knowledge can be used to predict oxygen input and design equipment for industries like biotechnology and pharmaceuticals.
Researchers use boron isotopes to identify sources and properties of fluids in subduction zones. They found that serpentinite-derived fluid drives metasomatism in continental subduction zones.
Researchers at Argonne National Laboratory discovered how microparticles can change direction when an electric stimulus is interrupted and reapplied with the same orientation. This emergent behavior has potential applications in microfluidic pumps for biomedical, chemical, and electronics applications.
Researcher Sepideh Razavi's work focuses on droplet wetting behavior, crucial for understanding disease transmission, industrial processes, and environmental sustainability. Her project aims to advance fundamental science for novel solutions in these fields.
Researchers have created a new method to generate strong fluid flows in tiny channels by heating a metal film with a laser beam, allowing for the separation and transport of nano-objects. This innovation has potential for lab-on-a-chip applications and could lead to advancements in nanoscale manufacturing and sensor technologies.
A study published in Science Advances reveals that individuals with less memory loss in old age tend to gain more knowledge, contrary to the previously assumed compensatory power of crystallized abilities. The findings suggest a strong dependency between changes in fluid and crystallized abilities.
Researchers at UC3M have developed a mathematical model that analyzes the appearance of oscillations in flow networks, which may help explain how blood circulates in the brain. The model takes into account the size of the network and predicts the frequency of pressure oscillations.
Researchers propose that water molecules interact with electrons in the nanotube walls, slowing down flow. Theoretical findings could significantly impact proposed carbon nanotube applications, such as filtering salt from seawater or generating energy.
Researchers developed a single-use sensor strip that can detect cerebrospinal fluid (CSF) leaks, providing a rapid diagnostic tool for patients with brain and spinal cord injuries. The test uses antibodies specific to proteins found in human CSF, detecting leaks even when other substances are present.
Researchers at Texas Tech University use supercomputers to analyze the dynamics of vortices and turbulence, finding that reconnection can lead to the formation of new structures. The study aims to improve fuel efficiency for cars and develop energy-saving aircraft designs.
The researchers developed an eye-like adaptive liquid lens that can be used to diverge or converge light by changing the shape of the DBA liquid. The lens exhibits high optical performance with good stability and can be used in various applications such as mobile phone cameras, endoscopes, and machine vision.
A large clinical trial involving over 5,000 patients found that commonly used saline solution is as effective at keeping people alive and their organs functioning as more expensive balanced solutions. The study's results provide greater certainty about the safety and benefits of saline solution for treatment.
University of Houston engineers Jiming Bao and Feng Lin create upward fountains in deep water by shining laser beams on the surface, attributing the phenomenon to the Marangoni effect. The discovery has potential applications in lithography, 3D printing, heat transfer, and microfluidics.
Researchers at MIT have developed a method to control the interaction between liquids and solids, allowing for the creation of surfaces with high or low wettability. This breakthrough has potential applications in various industries, including thermal management, protective coatings, and heat pipes.
A research team at the Beckman Institute for Advanced Science and Technology developed a chemical process to mimic trees' vascular systems in foamed polymers, adding structure and enabling directional fluid transport. The team discovered that increasing or decreasing gelation time enables direct control over the foam's cellular structure.
Researchers develop simplified version of large-scale invisibility cloak using fluid dynamics, controlling fluid flow speed and direction. The technique uses varying fluid channel thickness to conceal obstacles, restoring original streamline paths.
Researchers at Tel Aviv University successfully treated autism in animal models with medical cannabis oil, improving behavioral and biochemical parameters. The treatment showed significant improvement in compulsive and anxious behaviors, and a decrease in the concentration of the arousing neurotransmitter glutamate.
Black soldier fly larvae thrive in dense groups when given the right amount of airflow, reducing the risk of overheating. The research, published in Frontiers in Physics, aims to make these protein-rich insects more readily available as recyclers of food waste, which totals 1.3 billion tons per year.
Scientists at Tokyo University of Science have developed a novel polymer-based hydrogel that can prevent postoperative pancreatic fistulae, a frequent complication of pancreatic surgery. The Exceval hydrogel shows great promise for clinical applications due to its adjustable properties and high absorption abilities.
A new fluid has been created that can be molded and patterned using light, with potential applications in adaptive optics, mass transport, and microfluidics manufacturing. The fluid's surface tension is dependent on temperature, making it susceptible to laser manipulation.
A new coating developed by researchers at the University of Illinois Chicago uses thermoresponsive properties to create a hygroscopic slippery layer that prevents harmful substances from coming into contact with surfaces. This technology delays ice and frost formation, outperforming commercial products by up to ten times.
Researchers, led by UC Santa Barbara professor Björn Birnir and the University of Oslo's Luiza Angheluta, have published a complete description of boundary layer turbulence. The theory unites empirical observations with the Navier-Stokes equation into a mathematical formula.
The 74th APS Division of Fluid Dynamics Annual Meeting featured presentations on COVID-proofing daily life, kimchi physics, and extreme heat waves. Researchers also discussed advancements in fire-fighting trees and the science behind jellyfish engineers.
Researchers discovered that ants pass proteins through mouth-to-mouth exchanges to share metabolic labor and adapt to colony needs. This discovery sheds light on how ants divide tasks between individuals and the colony's life cycle.
A new study found that a simple surgical technique called posterior left pericardiotomy significantly reduces the risk of atrial fibrillation in patients undergoing cardiac surgery. The procedure, which involves draining excess fluid and small clots from the heart sac, was associated with a 56% lower incidence of irregular heart rhythm...
Researchers provide first direct measurement of overall impact of ocean eddy killing, finding a continuous loss of 50 gigawatts of kinetic energy. This phenomenon, known as 'eddy killing,' counterintuitively reduces the most energetic components of ocean currents.
Fish schools operate like superorganisms, with individual fish optimized for maximum surveillance and energy efficiency. Researchers discovered a 'perfect efficiency curve' in tail beats, allowing schools to conserve energy while monitoring their surroundings.
Researchers used a see-through porous medium to analyze polymer solutions' movement, overturning the assumption of uniform laminar flow. The polymers stretched out, creating turbulence and slowing the velocity of the flow.
Researchers develop efficient fog filter design using structured nylon nets to capture fog droplets, offering alternative source of fresh water in drought-stricken regions. The design is inspired by the unique abilities of Namib desert beetles and textile-based face masks.
Researchers at TU Wien have successfully described the 'teapot effect' with a theoretical analysis and experiments. The effect occurs when a liquid is poured out of a teapot too slowly, causing it to dribble down the outside of the pot due to an interplay of inertia, viscous, and capillary forces.
Researchers used computer simulations and experiments to find that dead zones in indoor spaces can linger with infectious aerosols up to 10 times longer than the rest of the room. This discovery highlights the need for ventilation systems based on air circulation within a room, rather than relying solely on air changes per hour.
A computer model developed by the University of Surrey researchers supports Bernard Williams' 40-year-old hypothesis that pressure changes cause fluid in the cavity to 'slosh', generating stress in the spinal cord tissue. The study shows that this process can lead to small cavities gradually expanding down the spinal cord.
Researchers found that females rely more heavily on aldosterone to regulate blood pressure, whereas males primarily use angiotensin II. This discovery could lead to targeted treatments for female hypertensive patients, improving treatment outcomes and reducing the risk of heart disease and stroke.
A research team led by Prof. NI Huaiwei found the mechanism and unmixing process of supercritical fluid, revealing spinodal decomposition as a key factor in phase separation. This discovery has important implications for the formation of magmatic hydrothermal deposits.
Liquid marbles' unique hydrophobic outer layer allows for faster evaporation than bare water droplets due to particle-particle and liquid-particle interactions. The team's mathematical model accurately predicts evaporation behavior, providing insights into these tiny biological structures.
Researchers found that a light breeze of about 5 mph extends effective social distancing by around 20% due to increased viral load persistence. Wearing masks outdoors reduces the chances of infection, with stronger winds increasing virus spread.
Researchers from Tokyo University of Science developed a computationally quick approach to predict molten droplet solidification on a solid surface. The model simulates the solidification process by considering the droplet behavior and heat transfer between the hotter droplet and cooler surface, replicating experiments with high accuracy.
University of Barcelona researchers discovered that chaotic flows in active fluids can be described by simple mathematical laws. The study used cytoskeletal proteins and enzymes to create an active fluid system surrounded by passive fluids, revealing new flow regimes and a theoretical framework to explain the results.
A recent study suggests that strike-slip faulting is an active deformation mechanism on Titan's surface, driven by diurnal tidal stresses and pore fluid pressures. The researchers found that shallow faults near the equator are optimally oriented for potential failure, which could facilitate material transport and affect habitability.
A new experimental method tracks the motion of fibers instead of particles to reveal previously hidden information about turbulent flows. The researchers developed an innovative solution using rigid fibers, which allowed them to measure the speed and direction of flow at two points a fixed distance apart.
Researchers at the University of Central Florida have identified food products that can alter a person's saliva to reduce the transmission potential of airborne pathogens. By adding ingredients like ginger, cornstarch, and xanthan gum to food products, people may be able to make masks more effective or even reduce their need for them.
Researchers designed a tubular phononic crystal to sense biochemical and physical properties of liquids. The device demonstrates sensitivity to liquid density and speed of sound, making it suitable for sensing applications.
A Korean research team has observed a long-lasting non-equilibrium phase coexistence in supercritical fluids, lasting several hours. The phenomenon is explained by a mass transport model at the phase coexistence interface, where nano-sized clusters facilitate transport.
Researchers have developed a new model for micro-swimmer-based transport, which shows that a swarm of micro-swimmers can transport particles more efficiently than traditional methods. The study's findings suggest that this phenomenon could be useful in biological applications, such as delivering drugs to specific locations in the body.
The NIST-developed emberometer uses digital cameras to track embers in mid-air and reconstruct their 3D shapes. This tool helps researchers understand the behavior of embers, which can aid in developing better protection for structures during wildfires.