Articles tagged with Plasma Theory
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Researchers at EAST have successfully accessed a theorized 'density-free regime' for fusion plasmas, achieving stable operation at densities beyond conventional limits. This breakthrough provides new insights into overcoming one of the most persistent physical obstacles on the path toward nuclear fusion ignition.
Hundreds of physicists from around the world will convene to present new research at the 67th annual meeting of the American Physical Society’s Division of Plasma Physics. The conference features presentations on fusion energy, plasma turbulence, laser plasma acceleration, and more.
The Department of Energy's Oak Ridge National Laboratory has been awarded $6.1 million to lead three research collaborations tackling fusion energy challenges. The projects focus on advanced materials, plasma diagnostics, and simulation technologies to accelerate the development of fusion energy.
A team of researchers used computer code M3D-C1 to model different valve configurations and found that six gas valves provide optimal protection for rapidly dispersing cooling gas. The study's findings will help bring fusion power closer to reality by advancing disruption mitigation strategies.
The EHT Collaboration unveils a new analysis of the supermassive black hole at the heart of galaxy M87, combining observations from 2017 and 2018. The study confirms the presence of a luminous ring with a shifted brightest region, indicating turbulent accretion disk dynamics.
Scientists at PPPL used a new method to develop plasma configurations that lose fewer energetic particles, addressing a major issue in stellarator designs. The alternative approach uses a proxy function to predict particle movement and has been applied to stellarators for the first time.
Researchers at Seoul National University have clarified the mechanism behind runaway electrons generated during tokamak fusion reactor startup. The binary nature of collisions facilitates runaway electron generation, addressing a theoretical bottleneck in fusion reactor design.
The SMall Aspect Ratio Tokamak (SMART) is a compact spherical tokamak that benefits from PPPL computer codes and expertise in magnetics and sensor systems. Negative triangularity is expected to offer enhanced performance by suppressing instabilities and preventing damage to the tokamak wall.
Researchers develop AI-driven catalyst discovery and simulate complex interactions to enhance hydrogen generation, carbon capture, and energy storage efficiency. The project aims to create a knowledgeable and skilled workforce capable of addressing critical challenges in the clean energy transition.
Scientists at the DOE's Princeton Plasma Physics Laboratory have directly observed magneto-Rayleigh Taylor instabilities in plasma, which could aid in understanding how black holes produce vast intergalactic jets. The observation confirms that magnetic fields play a crucial role in forming these jets.
Researchers at the University of Liverpool have achieved a significant milestone in converting carbon dioxide into valuable fuels and chemicals. They report a pioneering plasma-catalytic process for the hydrogenation of CO2 to methanol at room temperature and atmospheric pressure, achieving impressive selectivity rates.
Researchers at University of Rochester's Laboratory for Laser Energetics have developed a novel way to experimentally produce plasma 'fireballs' on Earth, generating high-density relativistic electron-positron pair plasmas. This breakthrough enables follow-up experiments that could yield fundamental discoveries about the universe.
Researchers found that a photon's polarization is topological, meaning it doesn't change as it moves through materials and environments. This property can help design better light beams for heating and measuring plasma, which could increase fusion efficiency.
Researchers analyzed 42 superflares using two models and concluded that hydrogen recombination is the most physically plausible explanation for high levels of energy. This model is supported by flare processes described in solar flares, which are well-studied phenomena.
Researchers discovered a new class of plasma oscillations that can exhibit extraordinary features, enabling innovative advancements in particle acceleration and fusion. This finding has significant implications for achieving clean-burning commercial fusion energy.
The H.E.S.S. Observatory detected gamma-ray emission from the outer jets of SS 433, revealing a shift in energy-dependent morphology. This suggests strong shock acceleration, where high-energy particles collide with photons, producing x-ray radiation and explaining the X-ray reappearance of the jets.
Energy beam-based direct and assisted polishing technologies for diamonds improve surface quality and material removal rates, overcoming limitations of traditional methods. Researchers analyzed four latest polishing techniques, including laser polishing, ion beam polishing, plasma-assisted polishing, and laser-assisted polishing.
The Vlasiator model demonstrated that two central theories on plasma eruptions in near-Earth space are simultaneously valid: magnetic reconnection and kinetic instabilities. This finding helps understand how these events occur and improves the predictability of space weather.
Researchers at Shibaura Institute of Technology have developed a faster way to synthesize CoSn(OH)6, a powerful catalyst required for high-energy lithium–air batteries. The new method uses solution plasma-based synthesis and achieves highly crystalline CSO crystals with improved catalytic properties.
Researchers at West Virginia University have developed a new theory that extends the first law of thermodynamics to systems not in equilibrium. This breakthrough has numerous potential applications across physics and other sciences, including studying plasmas in space and low-temperature plasmas.
Researchers create a hydrogen plasma with known temperature anisotropy, demonstrating the Weibel instability and its potential to seed galactic dynamo magnetic fields. The study uses a novel experimental platform to measure the complex topology of generated magnetic fields.
Researchers at the University of Rochester used x-ray spectroscopy to study radiation transport in dense plasmas. They found that atomic energy level changes do not follow conventional quantum mechanics theories, instead conforming to a self-consistent approach based on density-functional theory.
Researchers develop a new way to manufacture high-efficiency diffraction gratings using reactive ion-plasma etching, achieving near-theoretical unpolarized diffraction efficiency of 94.3%. The process enables robust and durable gratings suitable for harsh environments.
Researchers at Princeton Plasma Physics Laboratory have successfully applied boron powder to tungsten components in tokamaks, improving plasma confinement and reducing the risk of edge-localized modes. The innovative approach uses a PPPL-developed powder dropper to deposit boron coatings while minimizing disruptions to the magnetic field.
A new study proposes a mathematical tool to understand the fractal structure of quark-gluon plasma, which is formed in high-energy collisions. The fractal structure explains some phenomena seen in these collisions, including particle momentum distributions that follow Tsallis statistics.
A WVU postdoctoral researcher has made a groundbreaking discovery in the field of magnetic reconnection, which can be used to predict space weather events that affect satellite and power grid systems. The study uses advanced laser diagnostics to measure electron speeds, providing new insights into plasma physics processes.
A team of researchers used the National Ignition Facility (NIF) to create a laboratory replica of galaxy-cluster plasmas, discovering strong suppression of heat conduction in these turbulent environments. The experiments provide insight into complex physics processes and raise additional questions that may be answered in future studies.
Researchers at the DIII-D National Fusion Facility have successfully integrated hot cores and cool edges in fusion reactors using powder injection and Super H-mode. This approach achieves significant edge cooling with modest effects on core performance, making it compatible with larger devices like ITER. The results suggest a promising...
The PHAse Space MApping experiment, a complex plasma physics research project at WVU, aims to study the motion of ions and electrons in plasmas. The facility can measure three-dimensional motion at very small scales and is capable of performing detailed measurements.
The Wendelstein 7-X stellarator has demonstrated reduced neoclassical energy transport, lowering plasma energy losses. The optimised magnetic field successfully minimises these losses, a major weakness in conventional stellarators.
A Korean research team has identified the origin of bifurcated current sheets in the Earth's magnetosphere through theoretical analysis and simulations. The study reveals that these sheets naturally bifurcate during equilibration, resolving a long-standing mystery.
The study uses THz wave absorption to probe the temporal evolution of quasifree electrons in laser-induced plasma, showing a unique two-step decay characteristic. The researchers also find that as electron density increases, traps related to bound states saturate, leaving many electrons unsolvated.
Researchers discussed various topics in plasma physics, including the young solar wind, fusion experiments, and alternative approaches to killing bacteria and viruses. The findings highlight potential pathways for controlled nuclear fusion and applications of plasmas in energy production and medicine.
Researchers at Max-Planck-Institut für Plasmaphysik (IPP) have successfully simulated plasma edge instabilities in tokamaks, revealing trigger and course of instability. The simulation matches experimentally observed values, providing a crucial step towards predicting and avoiding ELM instabilities in future fusion devices.
Researchers at DOE's Princeton Plasma Physics Laboratory proposed a new theory to explain sawtooth instabilities in plasma, which could lead to more efficient fusion reactions. The theory suggests that localized instabilities can flatten pressure and temperature during the sawtooth cycle, explaining rapid heat collapses.
Researchers from the Technion Israel Institute of Technology used exploding electrical wires underwater to generate shock waves, revealing a slower decay rate than predicted by previous models. The findings support a simplified model that accurately describes the relationship between shock wave evolution and wire expansion.
Researchers at Far Eastern Federal University are studying the properties of quark-gluon plasma using a combination of lattice quantum chromodynamics and neural networks. The goal is to understand how this substance modifies with temperature and density changes.
A new publication by Kazan Federal University reviews ionosphere plasma experiments using artificial heating facilities like SURA, EISCAT-Heater, and HAARP. The study reveals insights into plasma fluctuations, turbulence, and electron acceleration, shedding light on the ionosphere's role as a natural plasma laboratory.
Scientists have detected the geodesic acoustic mode at two locations within an experimental fusion reactor for the first time. This new experimental setup will be a useful diagnostic tool for investigating zonal flows and their role in the L-H transition, crucial for regulating turbulence and particle transport.
Scientists have unraveled the behavior of electrical discharges on extremely small scales, revealing new insights into gas breakdown mechanisms. The study found that at these microscopic gap distances, no obvious discharge channel formed, and the voltage necessary for breakdown decreased linearly with decreasing gap distance.
A new study reveals unexpected discoveries about whistler waves, including wave reflections and cylindrical modes. The research provides insights into the nature of whistlers and space plasmas, which could aid in developing plasma technologies for spacecraft thrusters.
Researchers on the ISS investigated complex plasma behavior, discovering that microparticles exhibit nonuniform wave patterns in response to varying electrical fields. This discovery has implications for understanding astrophysical phenomena and dusty plasmas.
Japanese researchers at Osaka University propose that substances heated by high-power lasers produce an ultrahigh pressure plasma state comparable to stellar centers. The surface tension of this plasma can push back light, and the researchers derive a limit density for laser-induced hole boring.
The Max-Planck-Princeton Center has made significant progress in fusion research, investigating plasmas in astrophysics and advancing understanding of magnetic reconnection. New computer codes and experimentation have improved simulations, resolving long-standing questions about solar wind heating and magnetic field behavior.
Physicists Denis A. Baiko and Andrew A. Kozhberov studied the effects of strong magnetic fields and electron screening on ion motion in a Coulomb crystal. Their calculations can help understand the thermal evolution of neutron stars and white dwarfs.
Researchers developed a new inlet design for Hall thrusters that significantly increases thrust by creating a vortex in the discharge channel. The design improvement resulted in higher gas density and uniformity, leading to improved performance and increased specific impulse of up to 53.5%.
Researchers found a localized glow near the cathode surface due to enhanced ionization and electron confinement in the magnetic field. Increasing the magnetic field strength revealed a transition from order to chaos via a period-doubling route.
Researchers have successfully removed the neutralizer in plasma propulsion systems, enabling charge-neutral beams to be generated. This breakthrough is a significant improvement over traditional electric propulsion concepts.
Researchers used simulations to show that plasma from hypervelocity impacts creates damaging electromagnetic radiation by separating ions and electrons at different speeds. The study aims to verify the theory of senior author Sigrid Close, who previously suggested that hypervelocity impact plasmas are responsible for satellite failures.
Researchers have recreated the universe's origins and nature of matter by simulating high-energy nuclear collisions. The simulations show that the quark-gluon plasma exhibits a twisting, whirlpool-like structure, with swirling rings and vortices that can be measured experimentally.
A new experiment reproduces nature's patterns with a specially designed system called an H-shaped dielectric barrier discharge system. The system produces filaments of discharge plasma that can assume vast ranges of patterns in 3D, allowing scientists to explore complex mechanisms behind nature's diverse designs.
Researchers at PPPL have developed a new method that analyzes the plasma surrounding X-ray pulsars by coupling quantum mechanics with Einstein's special relativity. This technique can determine the density and field strength of the magnetosphere in greater detail than standard approaches.
Researchers have discovered a new super H-mode regime in tokamak plasmas, which could sharply boost fusion power production. The new state allows for higher pressure at the edge of the plasma, creating potential for increased power output from the superhot core.
Researchers at Princeton Plasma Physics Laboratory have discovered a new mechanism that speeds up magnetic reconnection, providing new insights into this complex astrophysical process. The model predicts a novel regime in which fast reconnection rates appear independent of system resistivity.
Researchers Padma Kant Shukla and Bengt Eliasson develop a unified theory explaining nonlinear dust acoustic shocks and solitary pulses in dusty plasmas. Laboratory experiments reveal large amplitude dust acoustic solitary pulses and shock waves, which their model successfully explains.
A new study demonstrates that magnetic forces correctly explain the motion of erupting plasma clouds, resolving a long-standing challenge in understanding coronal mass ejections (CMEs). The research uses data from the STEREO twin-satellite mission to validate a theoretical model of CMEs as giant 'magnetic flux ropes'.
The National Ignition Facility's first experiments successfully validated computer simulations for controlled laser-induced ignition. Researchers fired laser beams into gold-plated cylinders, creating X-rays that ablated and imploded a capsule to achieve brief bursts of energy.
Researchers at UD's Bartol Institute are using a new parallel computing facility to simulate coronal heating, a phenomenon that affects satellites and life on Earth. The simulations provide insights into the fundamental nature of space physics and plasma properties.
Physicists discuss new discoveries in plasmas, including solar eruptions triggered by magnetic flux ropes. Advances in plasmatrons for vehicles reduce pollution emissions, enabling more efficient engine operation.
Winglee's design harnesses solar wind to accelerate spacecraft, potentially reaching speeds of over 100km/s. The sailcloth is a magnetic field that repels ions and charged particles, exerting a small but steady force on the spacecraft.