Your search keyword '"Electrodynamics"' showing total 15,719 results

1. A recursive cell multipole method for atomistic electrodynamics models.

Author

Bronson Jr., Mark J. and Jensen, Lasse

Subjects

*RAMAN scattering, *FAST multipole method, *SERS spectroscopy, *ELECTRODYNAMICS, *CARTESIAN coordinates, *OPTICAL properties

Abstract

For large plasmonic nanoparticles, retardation effects become important once their length becomes comparable to the wavelength of light. However, most models do not incorporate retardation effects due to the high computational cost of solving for the optical properties of large atomistic electrodynamics systems. In this work, we derive and implement a recursive fast multipole method (FMM) in Cartesian coordinates that includes retardation effects. In this method, higher-order electrodynamic interaction tensors used for the FMM are calculated recursively, thus greatly reducing the implementation complexity of the model. This method allows for solving of the optical properties of large atomistic nanoparticles with controlled accuracy; in practice, taking the expansion to the fifth order provides a good balance of accuracy and computational time. Finally, we study the effects retardation has on the near- and far-field properties of large plasmonic nanoparticles with over a million atoms using this method. We specifically focus on nanorods and their dimers, which are known to generate highly confined fields in their junctions. In the future, this method can be applied to simulations in which accurate near-field properties are required, such as surface-enhanced Raman scattering. [ABSTRACT FROM AUTHOR]

Published

2024

2. Near-field thermal emission from metasurfaces constructed of SiC ellipsoidal particles.

Author

Walter, Lindsay P., McKay, Joseph C., Raeymaekers, Bart, and Francoeur, Mathieu

Subjects

*DELOCALIZATION energy, *ENERGY density, *SPECTRAL energy distribution, *MOLECULAR spectra, *ELECTRODYNAMICS

Abstract

We model near-field thermal emission from metasurfaces structured as two-dimensional arrays of ellipsoidal SiC particles. The modeling approach is developed from fluctuational electrodynamics and is applicable to systems of ellipsoidal particles within the dipole limit. In all simulations, the radial lengths of particles are restricted to the range of 10–100 nm, and interparticle spacing is constrained to at least three times the particle characteristic length. The orientation and dimensions of constituent ellipsoidal particles are varied to tune localized surface phonon resonances and control the near-field energy density above metasurfaces. Results show that particle orientation can be used to regulate the relative magnitude of resonances in the energy density, and particle dimensions may be changed to adjust the frequency of these resonances within the Reststrahlen band. Metasurfaces constructed from particles with randomized dimensions display comparatively broadband thermal emission rather than the three distinct resonances seen in metasurfaces made with ellipsoidal particles of equivalent dimensions. When the interparticle spacing in a metasurface exceeds about three times the particle characteristic length, the spectral energy density above the metasurface is dominated by individual particle self-interaction and can be approximated as a linear combination of single-particle spectra. When interparticle spacing is at the lower limit of three times the characteristic length, however, multiparticle interaction effects increase and the spectral energy density above a metasurface deviates from that of single particles. This work provides guidance for designing all-dielectric, particle-based metasurfaces with desired near-field thermal emission spectra, such as thermal switches. [ABSTRACT FROM AUTHOR]

Published

2023

3. Optical Conductivity and Photo‐Induced Polaronic Formation in Co2MnGa Topological Semimetal.

Author

Tomarchio, Luca, Macis, Salvatore, Mou, Sen, Mosesso, Lorenzo, Markou, Anastasios, Lesne, Edouard, Felser, Claudia, and Lupi, Stefano

Subjects

*ELECTRONIC band structure, *THIN films, *PHOTOCONDUCTIVITY, *POLARONS, *ELECTRODYNAMICS

Abstract

Topological materials occupy an important place in the quantum materials family due to their peculiar low‐energy electrodynamics, hosting emergent magneto‐electrical, and nonlinear optical responses. This manuscript reports on the optical responses for the magnetic topological nodal semimetal Co2MnGa, studied in a thin film geometry at various thicknesses. The thickness‐dependent optical conductivity is investigated, observing a substantial dependence of the electronic band structure on thickness. Additionally, details on the ultrafast response of the low energy excitations in the terahertz frequency are reported by employing optical pump‐terahertz probe (OPTP) spectroscopy. In particular, the photocarrier dynamics of Co2MnGa thin films is studied at varying pump fluence, pump wavelength, and film thickness, observing a negative THz photoconductivity which is assigned to a dynamical formation of large polarons in the material. [ABSTRACT FROM AUTHOR]

Published

2024

4. Nonlinear electrodynamics and its possible connection to relativistic superconductivity: an example.

Author

Bruce, Stanley A.

Subjects

*MAXWELL equations, *SUPERCONDUCTIVITY, *MAGNETIC fields, *ELECTRIC fields, *ELECTRODYNAMICS

Abstract

This work presents an illustrative example suggesting a potential connection between the Heisenberg–Euler (HE) model of nonlinear electrodynamics (NLED) and relativistic superconductivity. Within a cylindrical coordinate system, we derive nonlinear Maxwell's equations from the HE Lagrangian to the fourth order in the electromagnetic (EM) field. By considering static electric and magnetic fields with Gaussian radial profiles, we compute the corresponding HE current density. In parallel, we explore relativistic type-II superconductivity in analogy with the Ginzburg–Landau (GL) theory. We calculate the vortex-supercurrent density of the condensate and propose a link between this current and the HE current. This connection enables the derivation of the relativistic order parameter state. The problem considered in this article may contribute to the understanding of superconductivity in strong EM environments within the broader framework of NLED. [ABSTRACT FROM AUTHOR]

Published

2024

5. Braided Scalar Quantum Electrodynamics.

Author

Ćirić, Marija Dimitrijević, Nikolić, Biljana, Radovanović, Voja, Szabo, Richard J., and Trojani, Guillaume

Subjects

*SCALAR field theory, *GAUGE symmetries, *ELECTRODYNAMICS

Abstract

We formulate scalar electrodynamics in the braided L∞$L_\infty$‐algebra formalism and study its perturbative expansion in the algebraic framework of Batalin–Vilkovisky quantization. We also confirm that UV/IR mixing is absent at one‐loop order in this noncommutative field theory, and that the non‐anomalous Ward‐Takahashi identities for the braided gauge symmetry are satisfied. [ABSTRACT FROM AUTHOR]

Published

2024

6. Hamiltonian Formulation for Continuous Systems with Second-Order Derivatives: A Study of Podolsky Generalized Electrodynamics.

Author

Alawaideh, Yazen M., Lupas, Alina Alb, Al-khamiseh, Bashar M., Yousif, Majeed A., Mohammed, Pshtiwan Othman, and Hamed, Y. S.

Subjects

*ELECTRODYNAMICS, *SYSTEM dynamics, *EQUATIONS

Abstract

This paper presents an analysis of the Hamiltonian formulation for continuous systems with second-order derivatives derived from Dirac's theory. This approach offers a unique perspective on the equations of motion compared to the traditional Euler–Lagrange formulation. Focusing on Podolsky's generalized electrodynamics, the Hamiltonian and corresponding equations of motion are derived. The findings demonstrate that both Hamiltonian and Euler–Lagrange formulations yield equivalent results. This study highlights the Hamiltonian approach as a valuable alternative for understanding the dynamics of second-order systems, validated through a specific application within generalized electrodynamics. The novelty of the research lies in developing advanced theoretical models through Hamiltonian formalism for continuous systems with second-order derivatives. The research employs an alternative method to the Euler–Lagrange formulas by applying Dirac's theory to study the generalized Podolsky electrodynamics, contributing to a better understanding of complex continuous systems. [ABSTRACT FROM AUTHOR]

Published

2024

7. Direct Monitoring of Whole‐Brain Electrodynamics via High‐Spatiotemporal‐Resolution Photoacoustics with Voltage‐Sensitive Dye.

Author

Pang, Weiran, Zhu, Bowen, Li, Honghui, Zhou, Yingying, Woo, Chi Man, Huang, Xiazi, Zhong, Tianting, Lo, Hsuan, Wang, Laiyou, Lai, Puxiang, and Nie, Liming

Subjects

*SPATIAL resolution, *OPTICAL images, *ELECTRODYNAMICS, *VOLTAGE, *DETECTORS

Abstract

Brain voltage plays a crucial role in indicating internal functions or diseases, and optical voltage imaging has gained intensive attention in recent years. Despite encouraging progress, current implementations encounter limitations pertaining to penetration depth, field of view (FOV), and photostability of indicators. To mitigate these challenges, a robust voltage‐sensitive dye (VSD)‐based whole‐field photoacoustic brain detection (WF‐PABD) platform is proposed, enabling direct evaluation of voltage dynamics across the whole brain, forming as PA‐VSD. WF‐PABD is equipped with a 512‐element ring‐array ultrasound detector capable of 360‐degree scanning, providing a large FOV (≈5 cm), high spatial resolution (≈110 µm), and rapid imaging acquisition. The proposed VSD remained ≈75% photostability after 30 min laser exposure, much greater than most calcium sensors. The optical voltage‐response mechanisms are validated and the capability of PA‐VSD to directly screen seizures is established. It is demonstrated that investigating connectivity among different brain regions allows to identify the precise location of active epileptic foci as well as the electrical conduction pathways and their directionality through fast temporal visualization. In summary, this study not only addresses the need for non‐invasive, high‐resolution, long‐term, and direct monitoring of brain voltage but also empowers exciting venues for PA applications in neuroscience. [ABSTRACT FROM AUTHOR]

Published

2024

8. Recent results and outstanding questions on the response of the electrodynamics of the low latitude ionosphere to solar wind and magnetospheric disturbances.

Author

Fejer, Bela G., Navarro, Luis A., Chakrabarty, Dibyendu, Truhlik, Vladimir, and Yong-Qiang Hao

Subjects

*MAGNETIC storms, *SOLAR wind, *ELECTRIC currents, *ELECTRIC fields, *ELECTRODYNAMICS, *THERMOSPHERE

Abstract

Storm-time ionospheric electrodynamics effects have been the subject of extensive studies. The solar wind/magnetosphere/ionosphere and thermosphere disturbance wind dynamos have long been identified as the main drivers of low latitude storm-time electrodynamics. Extensive detailed studies showed that climatology of low latitude disturbance electric fields and currents is in good agreement with results from global theoretical and numerical models. Over the last decade, however, numerous studies have highlighted that the response of low latitude electrodynamics to enhanced geomagnetic activity is significantly more complex than previously considered. It is now clear that the electrodynamic disturbance processes are affected by a larger number of solar wind and magnetospheric parameters and that they also have more significant spatial dependence. This is especially pronounced during and after large geomagnetic storms when multiple simultaneous disturbance processes are also active. In this work, we briefly review the main past experimental and modeling studies of low latitude disturbance electric fields, highlight new results, discuss outstanding questions, and present suggestions for future studies. [ABSTRACT FROM AUTHOR]

Published

2024

9. Study of acoustic thin-shell wormholes with different types of matter distributions.

Author

Fatima, Ghulam, Javed, Faisal, Waseem, Arfa, Mustafa, Ghulam, and Tchier, Fairouz

Subjects

*EQUATIONS of state, *ELECTRODYNAMICS, *POSSIBILITY, *FLUIDS, *TOPOLOGY

Abstract

The development and stability of acoustic thin-shell wormholes (WHs) within the context of acoustic black holes are examined in this paper. Utilizing linearized radial perturbations, the stability of these WHs is examined. In this study, a variety of equations of state are taken into account, including barotropic, variable Chaplygin, and phantom-like equations of state. According to the findings, the acoustic black hole structure has an unstable configuration for barotropic fluid. However, as the parameter ℰ gets closer to zero, it does not show any stable or unstable configurations at the event horizon position. For higher values of n and ξ , the resulting structure for the phantom-like variable equation of state (EoS) displays stable behavior away from the horizon while presenting unstable configurations close to the event horizon. The possibility of a stable structure rises as n is increased. Additionally, the constructed structure exhibits stable behavior for n = 1 under extreme acoustic black holes, whereas thin-shell topologies demonstrate unstable behavior outside the event horizon for the generalized Chaplygin variable EoS. However, the structure stabilizes for n = 1 at higher values of ξ. The stability of acoustic thin-shell WHs is higher than that of Schwarzschild thin-shell WHs for smaller values of n , indicating that the acoustic black hole parameter greatly influences the stable configurations of thin-shell WHs. [ABSTRACT FROM AUTHOR]

Published

2024

10. The Characteristics of the Electro-Thermo-Convective Flow of a Dielectric Liquid Analyzed through the Electric Nusselt Number †.

Author

Koulova, Dantchi, Traore, Philippe, and Romat, Hubert

Subjects

NUSSELT number, FINITE volume method, LIQUID dielectrics, PRANDTL number, MAXWELL equations, STOKES equations

Abstract

This paper presents a fundamental study of electro-thermo-convective flows within a layer of dielectric liquid subjected to both an electric field and a thermal gradient. A low-conductivity liquid enclosed between two horizontal electrodes and subjected to unipolar charge injection is considered. The interplay between electric and thermal fields ignites complex physical interactions within the flows, all governed by a set of coupled electro-thermo-hydrodynamic equations. These equations include Maxwell, Navier–Stokes, and energy equations and are solved numerically using an in-house code based on the finite volume method. Electro-thermo-convective flows are driven by two dimensionless instability criteria: Rayleigh number Ra and the stability parameter T, and also by the dimensionless mobility parameter M and Prandtl number Pr. The electric Nusselt number (Ne) analogue to the Nusselt number (Nu) in pure thermal problems serves as an indicator to monitor the shift from a thermo- to an electro-convective flow and its eventual evolution into unsteady, and, later, chaotic flow. This change in regime is observed by tracking the electric Nusselt number's behavior as a function of the stability parameter (T), for different values of the non-dimensional parameters (M, Ra, and Pr). The important role of mobility parameter M for the development of the flow is shown. The flow structure during different development stages in terms of the number of convective cells is also discussed. [ABSTRACT FROM AUTHOR]

Published

2024

11. Observations and Simulations of a Double‐Core Hot Flow Anomaly.

Author

Lu, Xi, Otto, Antonius, Zhang, Hui, Liu, Terry, and Chen, Xingran

Subjects

*TRANSIENTS (Dynamics), *ELECTRODYNAMICS, *TURBULENCE, *MOON, *TUBES

Abstract

Hot Flow anomalies (HFAs), one of the most well‐analyzed transient phenomena in the Earth's foreshock, are known as kinetic structures driven by tangential discontinuities (TDs). Recently, a 2‐dimensional (2D) magnetohydrodynamics (MHD) model reproduced HFAs with either a high‐ or low‐density core. Further investigation of an HFA with two cores observed by the Magnetospheric Multiscale (MMS) mission is reported. The observation via the Acceleration, Reconnection, Turbulence and Electrodynamics of the Moon's Interaction with the Sun (ARTEMIS) mission suggests this MHD HFA is associated with a foreshock density hole‐like structure. The trailing flux tube in simulation may propagate with a TD in the foreshock. Our work suggests that HFAs with two low‐density cores can also be achieved in MHD process. Results show the total ram pressure can be an excellent diagnostic for the presence of transient structures, such as HFAs, at the bow shock. Plain Language Summary: The hot flow anomaly (HFA) is a typical foreshock transient on the upstream of Earth's bow shock. This phenomenon is characterized by heating and significant flow deflection inside its core region and is traditionally believed to be a kinetic structure associated with tangential discontinuities (TDs). More recently, HFA‐like structures have also been generated through magnetohydrodynamic (MHD) simulations. Here, we present an HFA with two low‐density cores captured by the Magnetospheric Multiscale (MMS) satellite. Observation from the Acceleration, Reconnection, Turbulence and Electrodynamics of the Moon's Interaction with the Sun (ARTEMIS) mission suggests the observed double‐core HFA is driven by foreshock density hole‐like structure, which is propagating with the observed TD to the bow shock. The observed double‐core HFA is reproduced by a 2‐dimensional (2D) MHD model, in which two low‐density flux tubes are inputted simultaneously. Our observation and simulations show that the total ram pressure is an excellent indicator for the presence of transient structures at the bow shock. Key Points: Double‐core hot flow anomalies can be reproduced by 2‐dimensional magnetohydrodynamic model with two simultaneous low‐density flux tubesThe simulation results and the observation show general agreementThe total ram pressure is an excellent indicator for the formation of hot flow anomalies at the bow shock [ABSTRACT FROM AUTHOR]

Published

2024

12. From quantum electrodynamics to a geometric gauge theory of classical electromagnetism.

Author

Marsh, Adam

Subjects

*QUANTUM field theory, *EQUATIONS of motion, *QUANTUM states, *PHASE velocity, *ELECTROMAGNETISM, *QUANTUM electrodynamics

Abstract

A relativistic version of the correspondence principle, a limit in which classical electrodynamics may be derived from quantum electrodynamics (QED), has never been clear, especially when including gravitational mass. Here we introduce a novel classical field theory formulation of electromagnetism, and then show that it approximates QED in the limit of a quantum state which corresponds to a classical charged continua. Our formulation of electromagnetism features a Lagrangian which is gauge invariant, includes a classical complex field from which a divergenceless four-current may be derived, and reproduces all aspects of the classical theory of charged massive continua without any quantum effects. Taking a geometric approach, we identify the four-current as being in the direction of extremal phase velocity of the classical field; the field equations of motion determine this phase velocity as being equal to the mass, which makes the rest density proportional to the squared modulus of the field. [ABSTRACT FROM AUTHOR]

Published

2024

13. A Potential Link between Space Weather and Atmospheric Parameters Variations: A Case Study of November 2021 Geomagnetic Storm.

Author

Regi, Mauro, Piscini, Alessandro, Francia, Patrizia, De Lauretis, Marcello, Redaelli, Gianluca, and Carnevale, Giuseppina

Subjects

*SPACE environment, *ZONAL winds, *MERIDIONAL winds, *SOLAR wind, *ELECTRODYNAMICS

Abstract

On 4 November 2021, during the rising phase of solar cycle 25, an intense geomagnetic storm (Kp = 8−) occurred. The effects of this storm on the outer magnetospheric region up to the ionospheric heights have already been examined in previous investigations. This work is focused on the analysis of the solar wind conditions before and during the geomagnetic storm, the high-latitude electrodynamics conditions, estimated through empirical models, and the response of the atmosphere in both hemispheres, based on parameters from the ECMWF ERA5 atmospheric reanalysis dataset. Our investigations are also supported by counter-test analysis and Monte Carlo tests. We find, for both hemispheres, a significant correspondence, within 1–2 days, between high-latitude electrodynamics variations and changes in the temperature, specific humidity, and meridional and zonal winds, in both the troposphere and stratosphere. The results indicate that, in the complex solar wind–atmosphere relationship, a significant role might be played by the intensification of the polar cap potential. We also study the reciprocal relation between the ionospheric Joule heating, calculated from a model, and two adiabatic invariants used in the analysis of solar wind turbulence. [ABSTRACT FROM AUTHOR]

Published

2024

14. EHD Instabilities in Two Layers of Insulating and Conducting Immiscible Liquids Subjected to Unipolar Charge Injection †.

Author

Koulova, Dantchi and Atten, Pierre

Subjects

THERMAL instability, INTERFACIAL tension, VISCOSITY, CHARGE injection, CHARACTERISTIC functions

Abstract

In this paper, the instability of two layers of insulating and conducting immiscible liquids separated by a deformable interface and subjected to unipolar injection is examined. Taking into account the slight deformation of the interface between the two liquids, a system of equations and boundary conditions is derived at marginal state. Non zero numerical solutions for both layers exist only for eigenvalues of the instability parameter T, which depends on the following parameters: injection level C, Bond number Bo, a new non-dimensional parameter P proportional to interfacial tension and the ratio of the layers' thickness and of liquids viscosity. The variations in the instability criterion Tc, corresponding to the smallest eigenvalue, are examined in detail as a function of the main characteristic parameters C, P and the Bond number. We find that for some values of P, two instability mechanisms convective and interfacial ones can take place. When the strength of interfacial tension or the liquid thickness ratio is very low, the critical number tends to a value corresponding to interfacial instability. The influence of injection-induced convection in the insulating layer and the effect of interfacial deformation on interfacial instability are also discussed. [ABSTRACT FROM AUTHOR]

Published

2024

15. Electrodynamic analysis of a sinusoidal antenna for small wave sizes

Author

Dmitry P. Tabakov and Wadzanai J. Zondai

Subjects

sinusoidal antenna, electrodynamics, integral equations, integral representation of the electromagnetic field, resonance, current distribution, Physics, QC1-999, Electronics, TK7800-8360

Abstract

Background. The work is aimed at developing and researching rigorous methods for calculating thin-wire structures with a complex generatrix shape, having small wave sizes, as well as studying the physical processes occurring in them. A special case of such structures is a sinusoidal antenna operating in a standing current wave mode. Aim. In progress the solution of internal and external problems of electrodynamics is carried out for a sinusoidal antenna of small wave sizes located above an infinitely extended ideal reflector. The currents on the elements of the structure are calculated, its input resistance and radiation characteristics are determined. Methods. The research is based on a strict electrodynamic approach, within the framework of which, for the specified structure in the thin-wire approximation, an integral representation of the electromagnetic field is formed, which, when considered on the surface of conductors together with boundary conditions, is reduced to a system of Fredholm integral equations of the second kind, written relative to unknown current distributions on conductors (internal task). Results. A mathematical model of the radiating structure is proposed, determined: the input resistance of the structure and the basic characteristics of its radiation. It is shown that the operating range of a sinusoidal antenna in the standing wave mode is determined by the quality factor of the input impedance resonances; An increase in the width of the sinusoidal conductor leads to a decrease in the resonant frequencies of the input resistance with a simultaneous increase in the quality factor of the resonances. Conclusion. From a practical point of view, the use of the considered structure allows significantly reduce the dimensions in comparison with a thin electric vibrator, however in this case, the operating range will be correspondingly narrowed, which is determined, due to the weak dependence of the radiation characteristics on frequency, by the quality factor of the resonances. The current distribution on the generatrix of the structure can be considered as a «projection» standing surface wave localized in the plane of a sinusoidal conductor, and resulting from the superposition of forward and backward surface (slow) waves propagating at a speed significantly lower than the speed of light. To further clarify the physics of the processes occurring in the structure, one should use spectral analysis of current functions and study the distributions of the electromagnetic field in the near zone of the structure.

Published

2024

16. Local density of states above a disk—Geometrical vs thermal boundary conditions.

Author

Biehs, Svend-Age, Kittel, Achim, and An, Zhenghua

Subjects

*DENSITY of states, *ELECTRODYNAMICS

Abstract

We analytically calculate the contribution to the local density of states due to thermal sources in a disk-like patch within the framework of fluctuational electrodynamics. We further introduce a wavevector cutoff method to approximate this contribution. We compare the results obtained with the source and cutoff method with the numerical exact local density of states above a metal disk attained by SCUFF-EM calculations. By this comparison, we highlight the difference and resemblance of thermal and geometrical boundary conditions which are both relevant for near-field scanning microscope measurements. Finally, we give an outlook to general lateral temperature profiles and compare it with surface profiles. [ABSTRACT FROM AUTHOR]

Published

2023

17. Only-phase Popov action: thermodynamic derivation and superconducting electrodynamics.

Author

Salasnich, L, Pelizzo, M G, and Lorenzi, F

Subjects

*ELECTRODYNAMICS, *ELECTROMAGNETIC coupling, *ELECTROMAGNETIC fields, *SUPERFLUIDITY, *SUPERCONDUCTORS, *ELECTROSTATIC fields

Abstract

We provide a thermodynamic derivation of the only-phase Popov action functional, which is often adopted to study the low-energy effective hydrodynamics of a generic nonrelativistic superfluid. It is shown that the crucial assumption is the use of the saddle point approximation after neglecting the quantum-pressure term. As an application, we analyze charged superfluids (superconductors) coupled to the electromagnetic field at zero temperature. Our only-phase and minimally-coupled theory predicts the decay of the electrostatic field inside a superconductor with a characteristic length much smaller than the London penetration depth of the static magnetic field. This result is confirmed also by a relativistic only-phase Popov action we obtain from the Klein–Gordon Lagrangian. [ABSTRACT FROM AUTHOR]

Published

2024

18. Advancements in Continuum Mechanics and Electrodynamics by a spacetime geometric approach.

Author

Romano, Giovanni and Barretta, Raffaele

Subjects

*CONTINUUM mechanics, *GEOMETRIC approach, *ELECTRODYNAMICS, *ELECTRIC charge, *SPACETIME

Abstract

Results achieved by the authors in the course of research activity on continuum mechanics and electrodynamics (CME) during the past twenty years are illustrated, revised and discussed. Adoption of a geometric approach leads to renewal of concepts and methods of classical CME and to formulation in Euclid (3+1)D ambient spacetime wherein innovation, clarity and depth of a geometric treatment naturally emerge. The dissemination of novel concepts and methods in CME is not delayable, with critical revisitation of problematic notions, analyses and results still currently on the scene. Material frame indifference, equilibrium in a reference configuration, extremality principles in Dynamics, finite elasticity, chain decomposition of finite strain in elasto-thermo-plasticity, variance of electro-magnetic induction laws under frame changes, action on electric charges moving in a magnetic field, are under the spotlight of innovation and advancement. Fostering basic knowledge of Differential Geometry and application of geometric notions and methods contribute effective tools in formulating meaningful rules, amending misstatements and dimming debates based on vague affirmations. [ABSTRACT FROM AUTHOR]

Published

2024

19. Weber–Maxwell electrodynamics: classical electromagnetism in its most compact and pure form.

Author

Kühn, S.

Subjects

*COMPUTATIONAL electromagnetics, *ATOMIC physics, *QUANTUM theory, *ELECTROMAGNETIC forces, *MAXWELL equations

Abstract

Weber–Maxwell electrodynamics is a modernized, compressed, cleansed and, in many respects, advantageous representation of classical electrodynamics that results from the Liénard-Wiechert potentials. In the non-relativistic domain, it is compatible with both Maxwell's electrodynamics and Weber electrodynamics. It is suitable for all electrical engineering tasks, ranging from electrical machines to radar and high-frequency technologies. Weber–Maxwell electrodynamics also simplifies access to quantum physics and other areas of modern physics, such as optics and atomic physics. Particular advantages of Weber–Maxwell electrodynamics are its simple and fast computability in computer calculations and, as it is based on point charges, in the simulation of plasmas. The latter is particularly important for fusion research. Moreover, Weber–Maxwell electrodynamics is also highly suited to academic and post-primary education, as it allows an easy comprehension of both magnetism and electromagnetic waves. Due to the novelty of Weber–Maxwell electrodynamics, there are currently no articles that summarize its most important aspects. The present article aims to achieve this. [ABSTRACT FROM AUTHOR]

Published

2024

20. Variability in the Electrodynamics of the Small Scale Auroral Arc.

Author

Krcelic, P., Fear, R. C., Whiter, D., Lanchester, B., and Brindley, N.

Subjects

AURORAS, ELECTRIC flux, ELECTRODYNAMICS, CURRENT sheets, PLASMA Alfven waves, ELECTRIC arc

Abstract

A statistical study has been made of dynamic small‐scale auroral events in order to understand the drivers of the large variability in the electrodynamics of auroral arcs at fine scales. We used the Auroral Structure and Kinetics (ASK) instrument, located on Svalbard, in order to measure various electrodynamic properties of fine scale auroral arcs. We performed Spearman and Kendall statistical tests and found two significant correlations. The first is between the mean precipitation flux and the variability of flux, which we assume is because of the dynamic and bursty nature of the acceleration mechanism and its dependence on Alfvén waves. The second correlation is between the variability of the precipitating electron flux and the variability of the tangential component of the electric field close to the arc and perpendicular to the magnetic field. We propose that both variabilities occur because of the variability of the upward (field‐aligned) current sheet in and around the arc, which is dynamic and non‐uniform. The correlation between the two variabilities can therefore be explained by their common source. Key Points: We report a statistical analysis of small scale electrodynamics, to better understand the drivers of small scale variabilityThere is a significant correlation between average flux and variability of the flux in our eventsThere is a significant correlation between variability of tangential component of the electric field and variability in fluxWe propose that variability of the dynamic non‐uniform field aligned current sheet would be a source of variability in both electric fields and in flux, causing them to be correlated [ABSTRACT FROM AUTHOR]

Published

2024

21. Physics-constrained machine learning for electrodynamics without gauge ambiguity based on Fourier transformed Maxwell's equations.

Author

Leon, Christopher and Scheinker, Alexander

Subjects

*MAXWELL equations, *FARADAY'S law, *PARTICLE beams, *FOURIER transforms, *ELECTRODYNAMICS, *MACHINE learning, *GYROTRONS

Abstract

We utilize a Fourier transformation-based representation of Maxwell's equations to develop physics-constrained neural networks for electrodynamics without gauge ambiguity, which we label the Fourier–Helmholtz–Maxwell neural operator method. In this approach, both of Gauss's laws and Faraday's law are built in as hard constraints, as well as the longitudinal component of Ampère–Maxwell in Fourier space, assuming the continuity equation. An encoder–decoder network acts as a solution operator for the transverse components of the Fourier transformed vector potential, A ^ ⊥ (k , t) , whose two degrees of freedom are used to predict the electromagnetic fields. This method was tested on two electron beam simulations. Among the models investigated, it was found that a U-Net architecture exhibited the best performance as it trained quicker, was more accurate and generalized better than the other architectures examined. We demonstrate that our approach is useful for solving Maxwell's equations for the electromagnetic fields generated by intense relativistic charged particle beams and that it generalizes well to unseen test data, while being orders of magnitude quicker than conventional simulations. We show that the model can be re-trained to make highly accurate predictions in as few as 20 epochs on a previously unseen data set. [ABSTRACT FROM AUTHOR]

Published

2024

22. Extended phase space thermodynamics of magnetized black holes with nonlinear electrodynamics.

Author

Kruglov, S. I.

Subjects

*PHASE space, *BLACK holes, *THERMODYNAMICS, *GIBBS' free energy, *ELECTRODYNAMICS, *SECOND law of thermodynamics

Abstract

Einstein's gravity in AdS space coupled to nonlinear electrodynamics (NED) with two parameters is studied. We investigate magnetically charged black holes. The metric and mass functions and their asymptotic are obtained showing that black holes may have one or two horizons. Thermodynamics in extended phase space was studied and it was proven that the first law of black hole thermodynamics and the generalized Smarr relation hold. The magnetic potential and the vacuum polarization conjugated to coupling (NED parameter), are computed and depicted. We calculate the Gibbs free energy and heat capacity. [ABSTRACT FROM AUTHOR]

Published

2024

23. Quantum refraction effects in pulsar emission.

Author

Kim, Dong-Hoon, Kim, Chul Min, and Kim, Sang Pyo

Subjects

*QUANTUM electrodynamics, *FARADAY effect, *NEUTRON stars, *REFRACTIVE index, *ELECTRODYNAMICS, *BIREFRINGENCE, *BINARY pulsars, *PULSARS

Abstract

Highly magnetized neutron stars exhibit the vacuum non-linear electrodynamics effects, which can be well-described using the one-loop effective action for quantum electrodynamics. In this context, we study the propagation and polarization of pulsar radiation, based on the post-Maxwellian Lagrangian from the Heisenberg–Euler–Schwinger action. Given the refractive index obtained from this Lagrangian, we determine the leading-order corrections to both the propagation and polarization vectors due to quantum refraction via perturbation analysis. In addition, the effects on the orthogonality between the propagation and polarization vectors and the Faraday rotation angle, all due to quantum refraction are investigated. Furthermore, from the dual refractive index and the associated polarization modes, we discuss quantum birefringence, with the optical phenomenology analogous to its classical counterpart. [ABSTRACT FROM AUTHOR]

Published

2024

24. The excitation energies and hyperfine structures for 2 l , 3 l states in lithiumlike ions.

Author

Li, Bing-Bing, Jiang, Jun, Wu, Lei, Zhang, Ru-Kui, Li, Xian-Jun, and Dong, Chen-Zhong

Subjects

*HYPERFINE structure, *ELECTRON configuration, *WAVE functions, *IONS, *ELECTRODYNAMICS

Abstract

Combining the multi-configuration Dirac–Hartree–Fock method and the model-quantum electrodynamics (QED) approach, the wave functions, transition energies and hyperfine structure constants for 2 l, 3 l states in Li-like Ne7+, Mg9+, Al10+, P12+, Ar15+ and Ca17+ ions are calculated. The effects of electron correlation, Breit interactions, nuclear recoil and QED effects are analyzed in detail. We find that the contribution of the non-diagonal elements of the self-energy is significant for the 2 p 1 / 2 → 2 s 1 / 2 and 2 p 3 / 2 → 2 s 1 / 2 transitions. However, for the 3 l → 2 s 1 / 2 transitions, the contribution of non-diagonal elements is small. The accuracy of the currently calculated hyperfine structure constants is expected to be within 1%. [ABSTRACT FROM AUTHOR]

Published

2024

25. Impulsive coupled systems with regular and singular ϕ-Laplacians and generalized jump conditions.

Author

Minhós, Feliz and Rodrigues, Gracino

Subjects

*NONLINEAR differential equations, *SPECIAL relativity (Physics), *IMPULSIVE differential equations, *DIFFERENTIAL equations, *NONLINEAR systems, *ELECTRODYNAMICS

Abstract

This work contains sufficient conditions for the solvability of a third-order coupled system with two differential equations involving different Laplacians, fully discontinuous nonlinearities, two-point boundary conditions, and two sets of impulsive effects. The first existing result is obtained from Schauder's fixed point theorem, and the second one provides also the localization of a solution via the lower and upper solutions technique. We point out that it is the first time that impulsive coupled systems with strongly nonlinear fully differential equations and generalized impulse effects are considered simultaneously. Moreover, the singular case is applied to a special relativity model in classical electrodynamics. [ABSTRACT FROM AUTHOR]

Published

2024

26. Electromagnetic–thermal–mass transport triple hybrid model for energy-efficient hydrogen release from metal particles by induction heating.

Author

Kobayashi, Chihiro and Tanabe, Katsuaki

Subjects

*INDUCTION heating, *HYDROGEN content of metals, *HYDROGEN as fuel, *HYDROGEN storage, *ELECTROMAGNETIC waves, *FUEL cell vehicles

Abstract

Hydrogen storage in metals is anticipated to be a highly promising technical approach for managing hydrogen in diverse energy applications, emphasizing the need to establish efficient operating conditions. In this study, we developed a numerical model that can simultaneously calculate hydrogen and heat transport combined with electromagnetic induction heating of metal particles. Using the developed numerical simulator, we investigated the behavior of the hydrogen release process from the hydrogen-absorbing metal and proposed important indicators for the operation. The fractions of the electromagnetic energy absorbed by the metal particle used for the hydrogen release, sensible heat, interfacial heat conduction, and thermal radiation were systematically evaluated. Considering the trade-off between temperature rise and the hydrogen concentration gradient, an optimal diameter of metal particles existed for the maximum hydrogen release rate. Similarly, the trade-off between temperature rise and energy consumption revealed an optimal electromagnetic power density for the heat utilization fraction for hydrogen release. Our electromagnetic–thermal–mass transport triple hybrid model constitutes a useful numerical simulator for the design of energy-efficient hydrogen storage systems. [Display omitted] • A novel numerical model for hydrogen transport is introduced. • Electromagnetic energy, thermal, and mass transport phenomena are combined. • Energy is tracked for hydrogen release, sensible heat, conduction, and radiation. • Optimal Ti particle diameter and electromagnetic power density are determined. • The model may aid in designing energy-efficient hydrogen storage systems. [ABSTRACT FROM AUTHOR]

Published

2024

27. The inverse problem within free Electrodynamics and the coisotropic embedding theorem.

Author

Schiavone, L.

Subjects

*INVERSE problems, *EMBEDDING theorems, *ELECTRODYNAMICS, *EQUATIONS of motion, *DIFFERENTIAL equations, *CALCULUS of variations

Abstract

In this paper, we present the coisotropic embedding theorem as a tool to provide a solution for the inverse problem of the calculus of variations for a particular class of implicit differential equations, namely the equations of motion of free Electrodynamics. [ABSTRACT FROM AUTHOR]

Published

2024

28. Late time decay of scalar and Dirac fields around an asymptotically de Sitter black hole in the Euler–Heisenberg electrodynamics.

Author

Bolokhov, S. V.

Subjects

*BLACK holes, *ELECTRODYNAMICS, *NUMERICAL analysis

Abstract

We compute the quasinormal modes of massive scalar and Dirac fields within the framework of asymptotically de Sitter black holes in Euler–Heisenberg non-linear electrodynamics. We pay particular attention to the regime μ M / m P 2 ≫ 1 , where μ and M denote the masses of the field and the black hole, respectively, and m P represents the Planck mass, covering a range from primordial to large astrophysical black holes. Through time-domain integration, we demonstrate that, contrary to the asymptotically flat case, the quasinormal modes also dictate the asymptotic decay of fields. Employing the 6th order WKB formula, we derive a precise analytic approximation for quasinormal modes in the regime μ M / m P 2 ≫ 1 without resorting to expansion in terms of the inverse multipole number. This analytic expression takes on a concise form in the limit of linear electrodynamics, represented by the Reissner–Nordström black holes. Our numerical analysis indicates the stability of the fields under consideration against linear perturbations. [ABSTRACT FROM AUTHOR]

Published

2024

29. Proca Electrodynamics Approach to The Massive Photon.

Author

Pereira da Silva, Jizreel

Subjects

ELECTRODYNAMICS, PHOTONS, ELECTROMAGNETIC fields, GAUGE invariance, PLANCK'S constant

Abstract

Copyright of Journal of Education & Science is the property of Republic of Iraq Ministry of Higher Education & Scientific Research (MOHESR) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

30. Performance of Rotation‐Symmetric Bosonic Codes in a Quantum Repeater Network.

Author

Li, Pei‐Zhe, Dias, Josephine, Munro, William J., van Loock, Peter, Nemoto, Kae, and Lo Piparo, Nicoló

Subjects

ERROR-correcting codes, QUANTUM communication, TELECOMMUNICATION systems, COST functions, LINEAR network coding, ELECTRODYNAMICS

Abstract

Quantum error correction codes based on continuous variables play an important role for the implementation of quantum communication systems. A natural application of such codes occurs within quantum repeater systems which are used to combat severe channel losses and local gate errors. In particular, channel loss drastically reduces the distance of communication between remote users. Here, a cavity‐quantum electrodynamics (QED) based repeater scheme is considered to address the losses in the quantum channel. This repeater scheme relies on the transmission of a specific class of rotationally invariant error‐correcting codes. Several rotation‐symmetric bosonic codes (RSBCs) are compared for encoding the initial states of two remote users connected by a quantum repeater network against the convention of the cat codes and the performance of the system is quantified by using the secret key rate. In particular, the number of stations required to exchange a secret key over a fixed distance is determined and establish the resource overhead. For higher‐loss codes, the results show that a secret key rate (SKR) value of 0.01 bit per channel use can be achieved at a distance of 10000 km, with an elementary distance of 1.3 km. [ABSTRACT FROM AUTHOR]

Published

2024

31. The Effective Potential of Scalar Pseudo-Quantum Electrodynamics in (2 + 1)D.

Author

Nascimento, Leandro O., Junior, Carlos A. P. C., and Santos, José R.

Subjects

PSEUDOPOTENTIAL method, ELECTRODYNAMICS, COULOMB potential, SCALAR field theory, PSEUDODIFFERENTIAL operators, QUANTUM electrodynamics, GAUGE field theory, HIGGS bosons

Abstract

The description of the electron–electron interactions in two-dimensional materials has a dimensional mismatch, where electrons live in (2 + 1)D while photons propagate in (3 + 1)D. In order to define an action in (2 + 1)D, one may perform a dimensional reduction of quantum electrodynamics in (3 + 1)D (QED4) into pseudo-quantum electrodynamics (PQED). The main difference between this model and QED4 is the presence of a pseudo-differential operator in the Maxwell term. However, besides the Coulomb repulsion, electrons in a material are subjected to several microscopic interactions, which are inherent in a many-body system. These are expected to reduce the range of the Coulomb potential, leading to a short-range interaction. Here, we consider the coupling to a scalar field in PQED for explaining such a mechanism, which resembles the spontaneous symmetry breaking (SSB) in Abelian gauge theories. In order to do so, we consider two cases: (i) by coupling the quantum electrodynamics to a Higgs field in (3 + 1)D and, thereafter, performing the dimensional reduction; and (ii) by coupling a Higgs field to the gauge field in PQED and, subsequently, calculating its effective potential. In case (i), we obtain a model describing electrons interacting through the Yukawa potential and, in case (ii), we show that SSB does not occur at one-loop approximation. The relevance of the model for describing electronic interactions in two-dimensional materials is also addressed. [ABSTRACT FROM AUTHOR]

Published

2024

32. Numerical methods of higher accuracy for solving problems of electrodynamics.

Author

Utebaev, Bakhadir, Utebaev, Dauletbay, and Orynbaeva, Zukhra

Subjects

*FINITE difference method, *FINITE differences, *PROBLEM solving, *FINITE element method, *ELECTRODYNAMICS, *DIFFERENTIAL-difference equations

Abstract

Difference schemes of high accuracy for solving three-dimensional non-stationary Maxwell equations are proposed. From the original problem, we pass to the problem for one sought-for vector function. The problem is considered in a parallelepiped with the simplest boundary conditions. The construction of difference schemes is conducted on the basis of the finite difference method and finite element method. The stability and convergence of the considered difference schemes in the class of smooth solutions of the original differential problem are proved. [ABSTRACT FROM AUTHOR]

Published

2024

33. Fundamental Physics with Neutron Stars

Author

Nättilä, Joonas, Kajava, Jari J. E., Bambi, Cosimo, editor, and Santangelo, Andrea, editor

Published

2024

34. On the nonlinear electrodynamics in a Lorentz-breaking scenario.

Author

Neres Júnior, E, Felipe, J C C, and Baêta Scarpelli, A P

Subjects

*ELECTRODYNAMICS, *DISPERSION relations, *GROUP velocity, *REFRACTIVE index, *LORENTZIAN function, *QUANTUM field theory

Abstract

In this work, we study a model in nonlinear electrodynamics in the presence of a CPT-even term that violates Lorentz symmetry. The Lorentz-breaking vector, in addition to the usual background magnetic field, produces interesting effects in the dispersion relations. The consequences on the vacuum refractive index and the group velocity are studied. Vacuum birefringence is discussed in the case the nonlinear electrodynamics is a Euler–Heisenberg model. [ABSTRACT FROM AUTHOR]

Published

2024

35. Mesoscale Auroral Curls in Antarctica.

Author

Li, Xing‐Yu, Zong, Qiu‐Gang, Hu, Ze‐Jun, Wang, Yong‐Fu, Liu, Jian‐Jun, Zhou, Xu‐Zhi, Yue, Chao, Wang, Shan, Xie, Zi‐Kang, Zhao, Xing‐Xin, Liu, Zhi‐Yang, Yin, Ze‐Fan, Zhao, Hua‐Yu, and Sun, Yi‐Xin

Subjects

*AURORAS, *METEOROLOGICAL satellites, *MAGNETOSPHERE, *FLOW velocity, *RADAR, *ELECTRODYNAMICS

Abstract

The morphology and motion of auroras have been widely studied due to their indications on magnetospheric processes. Here, we report a new kind of "auroral curls," which have wavelengths in the mesoscale (∼100 km) and propagate azimuthally. Utilizing data from the Chinese Antarctic Zhongshan Station (the all‐sky imager and the high‐frequency radar), the Active Magnetosphere and Planetary Electrodynamics Response Experiment and the Defense Meteorological Satellite Program, we analyze an event occurred on 23 April 2019. We find these curls are fine structures in the poleward boundary of multiple arcs. Corresponding field‐aligned currents manifest as a series of longitudinally arranged pairs, while ionospheric flow velocities nearby oscillate with periods in the Pc 5 band. Observational evidence suggests these curls are connected with ultra‐low frequency (ULF) waves, which opens the possibility of using auroras to globally image ULF waves. Plain Language Summary: Auroras caused by precipitation of magnetospheric particles contain information about physical processes happened in the magnetosphere. In this letter, we report a new kind of auroral dynamic forms observed in Antarctica. These structures present both spatial and temporal periodic characteristics, which have similar scales with those of magnetospheric ultra‐low frequency (ULF) waves. We propose these auroral forms are connected with ULF waves, which provides a potential method to globally image ULF waves by analyzing properties of these auroras. Key Points: Azimuthally propagating "auroral curls" with mesoscale wavelengths were observed in AntarcticaThese curls are fine structures in the poleward boundary of multiple arcs formed by longitudinal‐arranged field‐aligned current pairsIonospheric flow velocities nearby oscillate with periods in the Pc 5 band, indicating connections with ultra‐low frequency waves [ABSTRACT FROM AUTHOR]

Published

2024

36. An in silico analysis of neuromodulation for pain relief: Determining the role of classical electrodynamics.

Author

Cornish, Philip, Humphrey, Nabil, Cornish, Anne, and Emmerson, R. Branden

Subjects

*ANALGESIA, *ELECTRODYNAMICS, *NEUROMODULATION, *ELECTROMAGNETIC theory, *ELECTROMAGNETIC fields, *NEURAL stimulation

Abstract

There has been ongoing debate about the efficacy and mechanism of action of neuromodulation devices in pain relief applications. It has recently been suggested that both issues may be resolved if electromagnetic theory is incorporated into the understanding and application of this technology, and we therefore undertook an in silico analysis to further explore this idea. We created a CAD replication of a standard neuromodulation electrode array with a generic linear 3/6 mm 8‐contact lead, developed a parameterized algorithmic model for the pulse delivered by the device and assigned material properties to biologic media to accurately reflect their electromagnetic properties. We then created a physical simulation of the device's output both in air and in the biophysical environment. The simulations confirmed the presence of an electromagnetic field (EM field). Variations in programming of the device affected the strength of the EM field by orders of magnitude. The biologic media all absorbed the EM field, an effect which was particularly pronounced in cerebrospinal fluid and muscle. We discuss the implications of all these findings in relation to the literature. We suggest that knowledge of electromagnetic theory and its application within the biophysical space is required for the optimal use of neuromodulation devices in pain relief applications. [ABSTRACT FROM AUTHOR]

Published

2024

37. Modified FRW cosmology with massive gravity in the spectrum of the rainbow.

Author

Naeem, Muhammad and Bibi, Aysha

Subjects

*INFLATIONARY universe, *RAINBOWS, *GRAVITY, *PHYSICAL cosmology, *ELECTROMAGNETIC fields, *ELECTRODYNAMICS

Abstract

In this study, authors investigate a novel framework incorporating exponential electrodynamics and d-dimensional energy-dependent massive gravity. Our focus lies in demonstrating that a nonlinear electromagnetic field, acting as the gravitational source, leads to an accelerated expansion of the universe. Employing massive gravity's rainbow as a catalyst for cosmic evolution, the big bang singularity inherent in the model is successfully eliminated. This analysis reveals that the synergy between the magnetic universe and massive gravity's rainbow is the underlying cause of the observed accelerated cosmic expansion. The classical stability during the deceleration phase and ensure the causality of the model are established. Additionally, we delve into 4-dimensional energy-dependent cosmology. Furthermore, approximations for key cosmological parameters such as the running of the spectral index, tensor-to-scalar ratio, and, the spectral index are presented. These estimations closely align with observational data from PLANCK and WMAP, providing valuable insights into the compatibility of the proposed model with empirical evidence. [ABSTRACT FROM AUTHOR]

Published

2024

38. Novel regular black holes: geometry, source and shadow.

Author

Kar, Anjan and Kar, Sayan

Subjects

*BLACK holes, *MAGNETIC monopoles, *GEOMETRY, *ELECTRODYNAMICS, *GENERAL relativity (Physics)

Abstract

We propose a two-parameter, static and spherically symmetric regular geometry, which, for specific parameter values represents a regular black hole. The matter required to support such spacetimes within the framework of general relativity (GR), is found to violate the energy conditions, though not in the entire domain of the radial coordinate. A particular choice of the parameters reduces the regular black hole to a singular, mutated Reissner–Nordström geometry. It also turns out that our regular black hole is geodesically complete. Fortunately, despite energy condition violation, we are able to construct a viable source, within the framework of GR coupled to matter, for our regular geometry. The source term involves a nonlinear magnetic monopole in a chosen version of nonlinear electrodynamics. We also suggest an alternative approach towards constructing a source, using the effective Einstein equations which arise in the context of braneworld gravity. Finally, we obtain the circular shadow profile of our regular black hole and provide a preliminary estimate of the metric parameters using recent observational results from the EHT collaboration. [ABSTRACT FROM AUTHOR]

Published

2024

39. Local limit of non-local gravity: a teleparallel extension of general relativity.

Author

Tabatabaei, Javad, Baghram, Shant, and Mashhoon, Bahram

Subjects

*GENERAL relativity (Physics), *DARK energy, *COSMOLOGICAL constant, *GRAVITY, *ELECTRODYNAMICS

Abstract

We describe a general constitutive framework for a teleparallel extension of the general theory of relativity. This approach goes beyond the teleparallel equivalent of general relativity (TEGR) by broadening the analogy with the electrodynamics of media. In particular, the main purpose of this paper is to investigate in detail a local constitutive extension of TEGR that is the local limit of non-local gravity. Within this framework, we study the modified Friedmann–Lemaître–Robertson–Walker cosmological models. Of these, the most cogent turns out to be the modified Cartesian flat model which is shown to be inconsistent with the existence of a positive cosmological constant. Moreover, dynamic dark energy and other components of the modified Cartesian flat model evolve differently with the expansion of the universe as compared to the standard flat cosmological model. The observational consequences of the modified Cartesian flat model are briefly explored and it is shown that the model is capable of resolving the H 0 tension. [ABSTRACT FROM AUTHOR]

Published

2024

40. Addendum — Inertia modified by electromagnetic Abelian gauge transformations.

Author

Garat, Alcides

Subjects

*GAUGE invariance, *ELECTRODYNAMICS, *GAUGE field theory

Abstract

In this paper, we will analyze the relationship between both potentials in vacuum electrodynamics and their local gauge transformations. [ABSTRACT FROM AUTHOR]

Published

2024

41. On the Existence of Pure, Broadband Toroidal Sources in Electrodynamics.

Author

Canós Valero, Adrià, Borovkov, Dmitrii, Kalganov, Aleksandr, Dudnikova, Alexandra, Sidorenko, Mikhail, Dergachev, Pavel, Gurvitz, Egor, Gao, Lei, Bobrovs, Vjaceslavs, Miroshnichenko, Andrey, and Shalin, Alexander S.

Subjects

*ELECTRODYNAMICS, *PROPERTIES of matter, *MAGNETIC moments, *ELECTROMAGNETIC fields, *CURRENT distribution, *NANOELECTRONICS

Abstract

Multipoles are paramount for describing electromagnetic fields in many areas of nanoscale optics, playing an essential role in the design of devices in plasmonics and all‐dielectric nanophotonics. Challenging the traditional division into electric and magnetic moments, toroidal moments are proposed as a physically distinct family of multipoles with significant contributions to the properties of matter. However, the apparent impossibility of separately measuring their response sheds doubt on their true physical significance. Here, the possibility of selectively exciting toroidal moments is confirmed without any other multipole. A set of general conditions is developed that any current distribution must fulfill to be entirely described by toroidal moments and prove the results in an analytically solvable case. The new theory allows to design and verify experimentally an artificial structure supporting a pure broadband toroidal dipole response in the complete absence of the electric dipole and other "ordinary" multipole contributions. In addition, a structure capable of supporting a novel type of non‐radiating source is proposed‐ a "toroidal anapole," originating from the destructive interference of the toroidal dipole with the unconventional electromagnetic sources known as mean square radii. The results in this work provide conclusive evidence on the independent excitation of toroidal moments in electrodynamics. [ABSTRACT FROM AUTHOR]

Published

2024

42. Calculating the High-Latitude Ionospheric Electrodynamics Using a Machine Learning-Based Field-Aligned Current Model.

Author

Gowtam, V. Sai, Connor, Hyunju, Kunduri, Bharat S. R., Raeder, Joachim, Laundal, Karl M., Ram, S. Tulasi, Ozturk, Dogacan S., Hampton, Donald, Chakraborty, Shibaji, Owolabi, Charles, and Keesee, Amy

Subjects

INTERPLANETARY magnetic fields, MACHINE learning, ELECTRODYNAMICS, ELECTRIC potential, METEOROLOGICAL satellites, SOLAR wind, GEOMAGNETISM, LATITUDE

Abstract

We introduce a new framework called Machine Learning (ML) based Auroral Ionospheric electrodynamics Model (ML-AIM). ML-AIM solves a current continuity equation by utilizing the ML model of Field Aligned Currents of Kunduri et al. (2020, https://doi.org/10.1029/2020JA027908), the FAC-derived auroral conductance model of Robinson et al. (2020, https://doi.org/10.1029/2020JA028008), and the solar irradiance conductance model of Moen and Brekke (1993, https://doi.org/10.1029/92gl02109). The ML-AIM inputs are 60-min time histories of solar wind plasma, interplanetary magnetic fields (IMF), and geomagnetic indices, and its outputs are ionospheric electric potential, electric fields, Pedersen/Hall currents, and Joule Heating. We conduct two ML-AIM simulations for a weak geomagnetic activity interval on 14 May 2013 and a geomagnetic storm on 7-8 September 2017. ML-AIM produces physically accurate ionospheric potential patterns such as the two-cell convection pattern and the enhancement of electric potentials during active times. The cross polar cap potentials (ΦPC) from ML-AIM, the Weimer (2005, https://doi.org/10.1029/2004ja010884) model, and the Super Dual Auroral Radar Network (SuperDARN) data-assimilated potentials, are compared to the ones from 3204 polar crossings of the Defense Meteorological Satellite Program F17 satellite, showing better performance of ML-AIM than others. ML-AIM is unique and innovative because it predicts ionospheric responses to the time-varying solar wind and geomagnetic conditions, while the other traditional empirical models like Weimer (2005, https://doi.org/10.1029/2004ja010884) designed to provide a quasi-static ionospheric condition under quasi-steady solar wind/IMF conditions. Plans are underway to improve ML-AIM performance by including a fully ML network of models of aurora precipitation and ionospheric conductance, targeting its characterization of geomagnetically active times. [ABSTRACT FROM AUTHOR]

Published

2024

43. HIGH-FREQUENCY ELECTRODYNAMICS OF NANOSTRUCTURED MULTIBAND SUPERCONDUCTORS.

Author

KASATKIN, O. L., KALENYUK, O. A., POKUSINSKYI, A. O., FUTIMSKY, S. I., and SHAPOVALOV, A. P.

Subjects

SUPERCONDUCTORS, FLUX pinning, RADIO frequency, ELECTRODYNAMICS, SURFACE resistance, CRITICAL currents, LOW temperatures

Abstract

The effect of artificially created 0D and 1D structural defects' nanostructure formed by implanted dielectric nanoparticles or irradiation defects on microwave properties of high-Tc superconductor films is analysed based on the phenomenological theory for microwave response of type-II superconductors. The surface resistance is calculated for the Meissner and mixed states for such a kind of nanostructured type-II superconductor film. An emergence of nonlinear response caused by the entrance of microwaveinduced vortices in the film interior through its edges is also theoretically explored. The obtained results demonstrate that artificial defect nanostructure inside the superconductor can significantly improve its microwave characteristics in both the Meissner states and the mixed ones and increase the range of the linear microwave response. We also present results of experimental studies on microwave properties of hightemperature superconductor (HTS) films with artificial defect nanostructure formed by heavy-ion irradiation. Noticeable decreases of the surface resistance and enhancement of the linear response range at low temperatures are observed for moderately perirradiated HTS YBa2Cu3O7-x (YBCO) film exposed to irradiation by 3 MeV Au2+ ions at dose 1011 cm-2. These results are in agreement with the above-discussed phenomenological theory for microwave response of nanostructured superconductors. A theoretical model concerning the new unusual mechanism of the nonlinear radio-frequency (RF) response in multiband superconductors is also presented. This is a mechanism of nonlinearity based on the possible dissociation of Abrikosov's vortices in multiband superconductors into fractional components under the strong RF current action. We have calculated the RF complex resistivity in two-band superconductors and grounded an emergence of specific peculiarities at critical current density values corresponding to the vortex depinning and dissociation. [ABSTRACT FROM AUTHOR]

Published

2024

44. A modified Lorentz force law for point-like charged particles in classical electrodynamics.

Author

Hamilton, K., Tinoco, D. Iglesias, and Erdélyi, B.

Subjects

*LORENTZ force, *MAXWELL equations, *ELECTRODYNAMICS, *ANGULAR momentum (Mechanics), *BEAM dynamics, *PARTICLE accelerators

Abstract

In classical electrodynamics, the well-known Lorentz force law falls short of providing a satisfactory result for the trajectory of point-like charged particles when considering that particle's own self-force. While there have been many historical attempts, Gralla, Harte and Wald developed a new model for classical charged particles that is free from pathologies while being consistent with Maxwell's equations and conserves stress-energy. Expanding upon this approach, we derive a relativistically correct, modified Lorentz force law in vector form, which includes radiation reaction, and spin- and magnetic moment-dependent correction terms, suitable to be included in classical electrodynamics lectures and beam dynamics simulation tools. As by-products we obtain evolution equations for mass, spin angular momentum and the radiated power. We compare the new equations to the classical ones and use the new equations to conduct numerical simulations, showing that the results are free of any nonphysical artifacts, and which might be possible to test in future experiments at particle accelerators. The new equations foster improved insight into beam dynamics. [ABSTRACT FROM AUTHOR]

Published

2024

45. Dispersion and absorption effects in the linearized Euler–Heisenberg electrodynamics under an external magnetic field.

Author

Santos, G. R. and Neves, M. J.

Subjects

*MAGNETIC fields, *ELECTRODYNAMICS, *DENSITY currents, *DISPERSION (Chemistry), *REFRACTIVE index, *THEORY of wave motion

Abstract

In this paper, the effects of the Ohmic and magnetic density currents are investigated in the linearized Euler–Heisenberg (EH) electrodynamics (ED). The linearization is introduced through an external magnetic field, in which the vector potential of the EH ED is expanded around a magnetic background field that we consider uniform and constant in this paper. From the EH linearized equations, we obtain the solutions for the refractive index associated with the electromagnetic wave superposition, when the current density is ruled by the Ohm law, and in the second case, when the current density is set by an isotropic magnetic conductivity. These solutions are functions of the magnetic background (B) of the wave propagation direction (k). It also depends on the conductivity and on the wave frequency. As a consequence, the dispersion and the absorption of plane waves change when B is parallel to k in relation to the case of B perpendicular to k in the medium. The characteristics of the refraction index are related to direction of B and of the wave polarization, where there is an open discussion for the birefringence in this medium. [ABSTRACT FROM AUTHOR]

Published

2024

46. Examining the effects of a pre-noon annular Solar Eclipse on equatorial electrodynamics: Evidence for a subsequent post-noon enhancement in plasma density.

Author

Choudhary, R.K., St.-Maurice, J.-P., Ambili, K.M., and Tripathi, Keshav R.

Subjects

*SOLAR eclipses, *PLASMA density, *EQUATORIAL electrojet, *EQUATORIAL ionization anomaly, *ELECTRODYNAMICS

Abstract

On 26 December 2019, an annular solar eclipse occurred in the southern part of the Indian subcontinent, which falls within the Equatorial ElectroJet (EEJ) region. This presented an opportunity to study the effects of a high-obscuration annular solar eclipse (93.3%) and of the special tides that accompany an eclipse. Eclipses are known to affect the electrodynamics of the equatorial region and the distribution of plasma in the low-latitude ionosphere. On December 26, 2019, different phenomena were indeed seen over different time scales. Around the time of the eclipse, there was a depletion in the total electron content (TEC) of the ionosphere, as inferred from GNSS receiver systems placed along the eclipse path in and around the EEJ region. Magnetometer measurements indicated a weakening of the EEJ current in this area not just when the eclipse took place but for the rest of the day as well. Observations from a digital-ionosonde located in Trivandrum (8.52 ° N, 76.94 ° E; 0.33 ° N dip-latitude) revealed that the ionospheric F-layer moved downwards just after obscurity maximum. Shortly after the F region was observed to move back upward, a one-hour long strong blanketing sporadic E-layer was triggered even though there was only a weakening of the EEJ but no reversal in the associated magnetic perturbations. Simulations from our quasi-two dimensional model clearly show that though there was no Counter Electrojet, there was indeed a weakening of the zonal field on 26 December 2019 during the eclipse and the post-eclipse period. The overall weakening trend lasted until late afternoon. Other notable features were uncovered on a time scale of several hours after the passage of the eclipse. While the day-long weakening of the EEJ is consistent with special tides related to the lunar trajectory, we also observed unusually large amplitude undulations in both vertical-TEC and F 2 -region peak plasma density over a five-hour time scale, starting around 2:00 PM LT. These undulations were consistent with the zonal electric field variations reconstructed from the magnetometer data. [ABSTRACT FROM AUTHOR]

Published

2024

47. Theoretical Basis of Biomimetic Flexible Piezoelectric Acoustic Sensors for Future Customized Auditory Systems.

Author

Jung, Young Hoon, An, Jaehun, Hyeon, Dong Yeol, Wang, Hee Seung, Kim, Ingon, Jeong, Chang Kyu, Park, Kwi‐Il, Lee, Pooi See, and Lee, Keon Jae

Subjects

*PIEZOELECTRIC detectors, *AUDITORY pathways, *BIOMIMETIC materials, *SOUND pressure, *PIEZOELECTRICITY, *PHASES of matter, *EAR, *ACOUSTIC transducers

Abstract

Flexible piezoelectric sensors have been spotlighted as an essential human–machine interface (HMI) by obtaining high‐quality data from omnipresent biomechanical inputs. Because human voice is the most intuitive bio‐signal among them, flexible piezoelectric acoustic sensors (f‐PAS) have a potential to shift the paradigm of HMI technologies. Despite the reported outstanding performance such as high sensitivity and speaker recognition accuracy, the theoretical investigation of f‐PAS has been insufficient to realize future customized development, because sensing principles are fundamentally different from commercialized microphones. Here, a theoretical framework of self‐powered f‐PAS by using mechanical and electrical physics is introduced. First of all, the basic theory of f‐PAS is compared with the auditory system of human cochlear. Based on the biomimetic trapezoidal shape, the resonant frequencies are analyzed with various structural and material conditions. In addition, the piezoelectricity of f‐PAS is derived to predict the sensitivity and SNR prior to experiments. To investigate sensor properties under the medium condition that is similar to human ear, the acoustic responses depending on the states of matter are theoretically compared. Finally, the distance limit of f‐PAS is studied with the correlations between piezoelectricity and sound pressure, which would provide novel strategies of functional material design for future applications of f‐PAS. [ABSTRACT FROM AUTHOR]

Published

2024

48. THERE IS NO 'VELOCITY KICK' MEMORY IN ELECTRODYNAMICS.

Author

HERDEGEN, ANDRZEJ

Subjects

*ELECTRODYNAMICS, *VELOCITY, *MEMORY, *SPACETIME, *CONTRADICTION

Abstract

The memory effect in electrodynamics, as discovered in 1981 by Staruszkiewicz, and also analysed later, consists of an adiabatic shift of the position of a test particle. The proposed 'velocity kick' memory effect, supposedly discovered recently, is in contradiction to these findings. We show that the 'velocity kick' memory is an artefact resulting from an unjustified interchange of limits. This example is a warning against drawing uncritical conclusions for spacetime fields, from their asymptotic behavior. [ABSTRACT FROM AUTHOR]

Published

2024

49. Symplectic groupoids and Poisson electrodynamics.

Author

Kupriyanov, Vladislav G., Sharapov, Alexey A., and Szabo, Richard J.

Subjects

*GAUGE invariance, *GAUGE field theory, *ELECTRODYNAMICS, *GEOMETRIC approach, *GROUPOIDS, *PHASE space, *SEMICLASSICAL limits

Abstract

We develop a geometric approach to Poisson electrodynamics, that is, the semi-classical limit of noncommutative U(1) gauge theory. Our framework is based on an integrating symplectic groupoid for the underlying Poisson brackets, which we interpret as the classical phase space of a point particle on noncommutative spacetime. In this picture gauge fields arise as bisections of the symplectic groupoid while gauge transformations are parameterized by Lagrangian bisections. We provide a geometric construction of a gauge invariant action functional which minimally couples a dynamical charged particle to a background electromagnetic field. Our constructions are elucidated by several explicit examples, demonstrating the appearances of curved and even compact momentum spaces, the interplay between gauge transformations and spacetime diffeomorphisms, as well as emergent gravity phenomena. [ABSTRACT FROM AUTHOR]

Published

2024

50. The quantum luminiferous aether.

Author

Larson, D. J.

Subjects

*NEWTON'S law of gravitation, *PHYSICAL laws, *MAXWELL equations, *ETHER (Anesthetic), *WHITE dwarf stars

Abstract

A solid, two-component, quantum luminiferous aether is proposed to exist. Simple postulates are hypothesized, along with some physical laws and assignments. Derivations then lead to the equations of electrodynamics (Maxwell’s equations and the Lorentz force equation), Newton’s law of universal gravitation, and to two field-masses. The theory is shown to successfully meet the classic tests of general relativity: calculations for the advance of the perihelia, the Shapiro effect, and the gravitational redshift agree with experiment, and the experimental result concerning the bending of light in gravitational fields is also understood. Additionally, gravitational waves are understood, and the first of the field-masses allows for an understanding of what is presently known as dark matter. A new approach to analyzing dense objects such as white dwarfs and neutron stars is discussed, and since the theory has no singularity, a replacement for black holes is suggested. Replacing relativity with an absolute, realist, and physical model returns us to a flat Euclidean space and a separate time. Absolute simultaneity enables understanding of quantum mechanics. The underlying philosophical grounding is discussed. [ABSTRACT FROM AUTHOR]

Published

2024