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Search Results (316)

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52 pages, 19473 KB  
Review
An Overview of Chromic Transition Metal Oxide Thin Films
by Gheorghe Ghilețchii, Alexandru Varzari, Ştefan-Andrei Irimiciuc, Ján Lančok and Sergiu Vatavu
Materials 2026, 19(14), 2943; https://doi.org/10.3390/ma19142943 - 8 Jul 2026
Viewed by 78
Abstract
Transition metal oxides constitute an important materials platform for chromic phenomena because their optical response is strongly coupled to the changes in electronic structure, phase state, carrier concentration, and defect chemistry. This review discusses selected transition metal oxide thin films, with emphasis on [...] Read more.
Transition metal oxides constitute an important materials platform for chromic phenomena because their optical response is strongly coupled to the changes in electronic structure, phase state, carrier concentration, and defect chemistry. This review discusses selected transition metal oxide thin films, with emphasis on VO2 and other vanadium oxides, WO3, NiO, and TiO2. The review summarizes the structural and electronic characteristics of these representative oxide systems and highlights the role of phase composition, crystal structure, oxygen non-stoichiometry, and defect chemistry in determining their optical response. The main thin film preparation routes, including pulsed laser deposition, magnetron sputtering, sol–gel and aerosol spray methods, atomic layer deposition, chemical vapor deposition, electrochemical routes, and molecular beam epitaxy, are reviewed with respect their influence on obtained thin films. Particular attention is given to applications in thermochromic VO2-and electrochromic WO3/NiO-based smart windows, and transition metal oxide-based gasochromic hydrogen sensors. Key challenges related to transition temperature tuning, luminous transmittance, solar modulation, optical contrast, cycling stability, ion transport and large-area integration are also discussed. Overall this review provides a comparative overview of selected transition metal oxide thin films by connecting material chemistry and physics, thin film preparation technology and functionality. Full article
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21 pages, 31111 KB  
Article
Facing a Challenge: Partial Discharge Measurements and Monitoring in Electrified Vehicle Assets Under PWM Supply
by Gian Carlo Montanari, Muhammad Shafiq, Riddhi Ghosh and Zhaowen Chen
Electronics 2026, 15(14), 2977; https://doi.org/10.3390/electronics15142977 - 8 Jul 2026
Viewed by 156
Abstract
Increasing power density of electrical devices in electrified transportation is an irreversible trend which involves power electronic-type supply, higher voltage and temperature. However, fast converter-switch rise times, high modulation and carrier frequencies, harmonics, and increased design field and temperature constitute potential causes of [...] Read more.
Increasing power density of electrical devices in electrified transportation is an irreversible trend which involves power electronic-type supply, higher voltage and temperature. However, fast converter-switch rise times, high modulation and carrier frequencies, harmonics, and increased design field and temperature constitute potential causes of accelerated electrothermal aging of insulation, especially if harmful phenomena, as partial discharges (PDs), incept. This paper focuses on solving issues related to PD monitoring under power electronics waveforms, dealing with effective and automatic tools for noise rejection and for the identification of the type of source generating PD, the latter being fundamental for quality control, diagnostic and condition maintenance. It is shown that innovative techniques are available, which allow PD to be measured even under fast switching (rise time) and high frequency, separating, in the time domain, PD pulses from switching noise. This approach can be carried out automatically by the PD detector software presented here, not requiring experts for measurement management and, thus, making it a feasible tool also for on-line PD monitoring and condition-based maintenance. PD monitoring results from accelerated aging tests on a motor under pulse-width modulation (PWM supply) are presented. In order to assess the insulation health condition, progressive degradation of the motor is quantified using a dynamic health index (DHI), primarily based on key PD parameters, i.e., PD magnitude, repetition rate, and likelihood of discharge type (surface or internal). The proposed DHI approach not only provides meaningful metrics for translating PD data into a diagnostic tool, but it also offers insights into residual life estimation and failure risk prediction. Full article
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19 pages, 14943 KB  
Article
Photochemical Decomposition and Aging-Induced Recrystallization in MAPLE-Deposited PLCL-PEG-PLCL Thin Films
by Simona Brajnicov, Valentina Dinca, Anca Florina Bonciu, Valentina Marascu, Antoniu Moldovan, Maria Dinescu and Catalin-Daniel Constantinescu
Coatings 2026, 16(7), 787; https://doi.org/10.3390/coatings16070787 - 1 Jul 2026
Viewed by 182
Abstract
The long-term stability of biodegradable polymer coatings deposited by matrix-assisted pulsed laser evaporation (MAPLE) remains insufficiently understood, particularly under ultraviolet irradiation conditions where photochemical effects may accompany material transfer. In this work, thin films of poly(lactide-co-caprolactone)-block-poly(ethyleneglycol)-block-poly(lactide-co-caprolactone), also known as PLCL-PEG-PLCL, are deposited from [...] Read more.
The long-term stability of biodegradable polymer coatings deposited by matrix-assisted pulsed laser evaporation (MAPLE) remains insufficiently understood, particularly under ultraviolet irradiation conditions where photochemical effects may accompany material transfer. In this work, thin films of poly(lactide-co-caprolactone)-block-poly(ethyleneglycol)-block-poly(lactide-co-caprolactone), also known as PLCL-PEG-PLCL, are deposited from chloroform solutions by UV-MAPLE using a nanosecond Nd:YAG laser operating at 266 nm over a wide laser fluence range (0.25–0.9 J/cm2). The effect of laser fluence on the morphological, structural, and chemical evolution of the coatings is investigated by atomic force microscopy (AFM), scanning electron microscopy (SEM), Fourier-transform infrared spectroscopy (FTIR), energy-dispersive X-ray spectroscopy (EDS), focused ion beam scanning electron microscopy (FIB-SEM), and X-ray diffraction (XRD). At low laser fluence, relatively homogeneous coatings are obtained while largely preserving the characteristic functional groups of the triblock copolymer. Increasing the laser fluence progressively induces surface restructuring phenomena, including droplets, wrinkles, and the appearance of highly symmetric faceted structures. These entities develop preferentially in samples deposited at elevated fluence and frequently appear only after prolonged aging under ambient conditions, revealing delayed recrystallization behaviour associated with metastable species generated during the deposition process. EDS analyses reveal localized chlorine enrichment within the faceted structures, while FIB-SEM investigations show porous internal morphologies. XRD confirms that the polymer matrix remains predominantly amorphous. The combined observations suggest that UV-MAPLE deposition from chloroform involves not only physical material transfer but also photochemical processes that promote decomposition, recombination, and delayed crystallization phenomena. A phenomenological model describing the successive stages of surface evolution, aging, and recrystallization is proposed. These results provide new insight into the long-term evolution of laser-deposited biodegradable polymer coatings and highlight the importance of solvent selection and processing conditions in determining their stability. Full article
(This article belongs to the Section Thin Films)
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68 pages, 18663 KB  
Review
Bridging the Gap Between Extreme Environments and Precision Measurements: Recent Progress in Megagauss Physics
by Shojiro Takeyama
AppliedPhys 2026, 2(2), 6; https://doi.org/10.3390/appliedphys2020006 - 22 Jun 2026
Viewed by 172
Abstract
Ultrastrong magnetic fields, ranging from 100 T to 1000 T, are generated exclusively by destructive pulsed magnets. While various generation methods exist, this review focuses on the Single-Turn Coil (STC) and Electromagnetic Flux Compression (EMFC) techniques, which provide optimal environments for high-precision measurements [...] Read more.
Ultrastrong magnetic fields, ranging from 100 T to 1000 T, are generated exclusively by destructive pulsed magnets. While various generation methods exist, this review focuses on the Single-Turn Coil (STC) and Electromagnetic Flux Compression (EMFC) techniques, which provide optimal environments for high-precision measurements in materials science. First, we present recent technological breakthroughs in the EMFC method that have successfully achieved fields exceeding 1000 T. We then describe specialized measurement infrastructures for magneto-optics, magnetization, and magneto-transport, highlighting the development of miniaturized all-plastic cryostats and custom sample holders designed for the dual extremes of cryogenic temperatures and megagauss fields. Representative physical phenomena revealed through these techniques are discussed, including quantum phase transitions in frustrated magnets, Aharonov–Bohm effects in carbon nanotubes, and semiconductor-to-metal transitions in strongly correlated systems. Furthermore, we address emerging measurement platforms such as magnetostriction, specific heat, and ultrasound velocity. Throughout this review, we emphasize the instrumentation and experimental refinements that ensure reliable data acquisition in the ultrastrong pulsed field regime. Full article
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23 pages, 3433 KB  
Article
Exact Nonlinear Wave Solutions and Interaction Dynamics of the Integrable Kairat-II-X Equation via Improved Riccati Neural Networks
by Ghulam Hussain Tipu, Fengping Yao, Abdul Mateen, Taha Radwan, Karim K. Ahmed and Abeer S. Khalifa
Mathematics 2026, 14(12), 2048; https://doi.org/10.3390/math14122048 - 8 Jun 2026
Viewed by 254
Abstract
This article studies the nonlinear wave dynamics of the recently introduced integrable combined Kairat-II-X (K-II-X) equation, which combines dynamical features of the Kairat-II and Kairat-X models. The considered model possesses relevance in nonlinear wave propagation, geometric curve dynamics, and localized optical pulse evolution, [...] Read more.
This article studies the nonlinear wave dynamics of the recently introduced integrable combined Kairat-II-X (K-II-X) equation, which combines dynamical features of the Kairat-II and Kairat-X models. The considered model possesses relevance in nonlinear wave propagation, geometric curve dynamics, and localized optical pulse evolution, thereby providing a mathematical framework for describing curvature-driven nonlinear phenomena in higher-dimensional systems. To obtain exact analytical solutions, a symbolic neural analytical framework based on the improved Riccati neural networks (IRNNs) method is employed. The proposed framework integrates trial functions within multilayer neural network structures, where each neuron in the first hidden layer is constructed through solutions of the improved Riccati equation. The symbolic outputs obtained from the neural network computations are subsequently employed as trial functions for the integrable combined K-II-X equation. Using this framework, several classes of exact wave solutions are derived in the form of hyperbolic, trigonometric, rational, including localized solitary waves and interaction-type structures. In particular, the symbolic neural representation produces both single- and multisoliton wave profiles exhibiting nonlinear localization and interaction behavior. Furthermore, representative wave structures are illustrated through two-dimensional, three-dimensional, contour, and density visualizations to examine the qualitative influence of governing parameters on wave amplitude, localization, propagation behavior, and interaction patterns. The reported results demonstrate the capability of the IRNNs framework to generate diverse nonlinear wave structures in integrable higher-dimensional systems and provide a useful analytical reference for future investigations in nonlinear science and applied mathematical physics. Full article
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20 pages, 6999 KB  
Article
Flow Resonance-Induced Temperature Rise for Thermal Impact Enhancement of Cavitation Reactor Systems
by Mou-Yung Liao, Sih-Li Chen, Li Xu, Yu-Hsiang Pan, Xin-Yuan Wu, Po-Hsien Wu, Jong-Fu Yeh, Yu-Yuan Hsieh, Kuan-Che Lan, Yi-Tung Chen and Bin-Juine Huang
Appl. Sci. 2026, 16(12), 5729; https://doi.org/10.3390/app16125729 - 6 Jun 2026
Viewed by 208
Abstract
It has been observed in prior research that high thermal impact—resulting from a large temperature difference between hot water vapor and cold liquid water—can enhance the thermal performance of cavitation-induced low-energy nuclear reactions (LENRs) in water, with an estimated increase in the coefficient [...] Read more.
It has been observed in prior research that high thermal impact—resulting from a large temperature difference between hot water vapor and cold liquid water—can enhance the thermal performance of cavitation-induced low-energy nuclear reactions (LENRs) in water, with an estimated increase in the coefficient of performance (COP) of approximately 50% for every 100 °C temperature rise. The temperature of the hot water vapor is primarily determined by the boiler output, which typically represents the highest temperature source and plays a dominant role in reactor performance. In this study, a flow oscillator was designed as an thermal conditioning component for these potential LENR reactor systems using linear flow network analysis (LFNA) to generate flow resonance that elevates the hot vapor temperature, thereby increasing thermal impact and improving LENR performance. LFNA is based on the linearization of the fluid flow equations governing mass and momentum transport and utilizes a fluid-electric circuit analogy. For a fluid flow system, various components can be modeled using analogs of electrical resistance, capacitance, and inductance (R, C, and L), allowing the system behavior to be analyzed similarly to an RLC circuit. Through this analogy, flow resonance phenomena can be predicted, potentially enabling the generation of high-temperature and high-pressure responses that are beneficial to LENR processes. The analytical model was experimentally validated and subsequently applied in the LENR reactor design. The analytical result shows that an output temperature difference exceeding 350 °C can be achieved using a 0.5 m pulse tube at a 46 Hz triggering frequency with 20 kPa perturbation, which indicates a potential COP enhancement of 175% based on prior studies. The result provides a potential mechanism to significantly enhance the thermal impact conditions and promote LENR performance in water-based reactor systems. Full article
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23 pages, 3649 KB  
Review
Evolution Mechanisms of Diffusion-Induced Phase Transformation Layers in Gun-Barrel Bores Under Thermochemical Coupling
by Jinghua Cao, Yiming Liu, Mengran Zhu, Jiawei Fu, Yao Jiang, Zheng Li, Ying Liu and Jingtao Wang
Metals 2026, 16(6), 623; https://doi.org/10.3390/met16060623 - 5 Jun 2026
Viewed by 302
Abstract
This study focuses on a 155 mm 32CrNi3MoV steel barrel and presents a thermochemically coupled phase transformation and diffusion dynamics model. The model leverages the significant disparity between radial and axial temperature gradients to simplify the heat conduction problem to a one-dimensional transient [...] Read more.
This study focuses on a 155 mm 32CrNi3MoV steel barrel and presents a thermochemically coupled phase transformation and diffusion dynamics model. The model leverages the significant disparity between radial and axial temperature gradients to simplify the heat conduction problem to a one-dimensional transient formulation. The temperature field distribution during firing sequences is solved analytically, accounting for the dynamic shift in critical phase transformation temperatures under high heating rates. The evolution of the martensitic layer thickness under repeated thermal shock is subsequently calculated. A numerical model for the pulsed diffusion of C and N is established based on Fick’s second law, incorporating the competitive diffusion–phase transformation mechanisms that govern martensite/austenite interface migration. To quantitatively evaluate the synergistic contribution of C and N to austenite stabilization, a carbon equivalent (Ceq) model is introduced, with the weight coefficient of N relative to C determined to be 0.68 and the critical Ceq required to lower the martensite start temperature below 25 °C calculated as 1.15 wt%. Concurrently, the microstructure and elemental distribution within the austenite layer of the retired barrel are systematically characterized using multi-scale techniques. The results indicate that the austenite layer on the inner bore surface arises from the synergistic effects of cyclic thermal-shock-induced phase transformation and elemental diffusion. Based on the Ceq criterion, the austenite layer thickness increases rapidly during the initial ~100 firing cycles, after which the growth rate slows significantly: it reaches approximately 1.27 μm after the first cycle and 2.94 μm after 1000 cycles, with only 0.2 μm of additional thickening between 100 and 1000 cycles—consistent with the experimentally observed range of 1.52–4.16 μm. The martensitic layer formed during the first firing cycle exhibits low thermal conductivity, which impedes subsequent heat transfer and leads to stabilization of its thickness at a characteristic depth. Grain refinement induced by repeated thermal shock provide short-circuit diffusion paths for elemental diffusion, accelerating compositional homogenization within the austenite layer and resulting in a stepped concentration profile at the interface. This study provides a representative example of non-equilibrium coupled phase transformation–diffusion phenomena under extreme transient loading. The established thickness prediction model can provide guidance for service life assessment of large-caliber barrels, offering both theoretical foundations and practical engineering guidance for their material design and performance optimization. Full article
(This article belongs to the Special Issue Advances in Forming and Heat Treatments of Metallic Materials)
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21 pages, 3207 KB  
Article
Exploring Qualitative Analysis and Interaction Dynamics in a (3+1)-Dimensional Boussinesq Equation II via Hirota Bilinear Method
by Ali Danladi, Aljethi Reem Abdullah, Ejaz Hussain and Beenish
Mathematics 2026, 14(11), 1981; https://doi.org/10.3390/math14111981 - 3 Jun 2026
Viewed by 246
Abstract
In this work, we explore the nonlinear wave phenomena of the (3+1)-dimensional Boussinesq (II) equation, a significantly higher-dimensional model that describes dispersive wave propagation in fluid dynamics, plasma systems, and nonlinear optics. Using exact analytic and qualitative dynamic approaches, we study a wide [...] Read more.
In this work, we explore the nonlinear wave phenomena of the (3+1)-dimensional Boussinesq (II) equation, a significantly higher-dimensional model that describes dispersive wave propagation in fluid dynamics, plasma systems, and nonlinear optics. Using exact analytic and qualitative dynamic approaches, we study a wide range of solutions and stability characteristics of the model. Initially, we use the Hirota bilinear method to obtain a number of exact solutions, such as breather waves, two-wave interaction solutions, and other types of localized nonlinear waves. These solutions display remarkable physical properties, including periodic energy trapping, oscillatory modulations, and nonlinear wave interactions in higher dimensions. In addition, the (m+1G)-expansion method is used to derive new soliton solutions, such as bright solitary waves and W-shaped solitons, which are found to be stable and undergo pulse-shaping dynamics under certain conditions. Three-dimensional, two-dimensional, and contour plots are displayed for some of the solutions to demonstrate the physical significance of the results. The visualizations reveal the presence of localized waves, wave interactions, periodical breathing, and stable soliton profiles. Furthermore, we conduct modulation instability analysis to describe the conditions under which small perturbations of continuous wave backgrounds are unstable. The dispersion relation and the instability gain spectrum are obtained, which explain the formation of breathers, soliton trains, and other coherent structures. Furthermore, a Galilean transformation converts the governing equation into a planar nonlinear dynamical system, enabling its qualitative study. The Hamiltonian structure is revealed, and the fixed points are identified as centers, saddles, and cusps through bifurcation analysis. To investigate more complex dynamics, a periodic forcing term is introduced into the system, resulting in chaos in the forced system. The chaotic behavior is confirmed via phase portraits, three-dimensional attractors, time series, Poincaré sections, return maps, fractal dimension, and positive Lyapunov exponents. We also perform a sensitivity test to show the effect of initial condition variations on the system’s long-term dynamics. The findings greatly expand the exact solution set and dynamics of the (3+1)-dimensional Boussinesq equation (II). The analytical approach presented in this paper can also be applied to other multidimensional nonlinear evolution equations of mathematical physics. Full article
(This article belongs to the Special Issue Advances in Nonlinear Analysis and Applications)
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16 pages, 760 KB  
Review
Neutron Capture in Evolved Red Giants: A Review
by Maurizio Maria Busso
Galaxies 2026, 14(3), 58; https://doi.org/10.3390/galaxies14030058 - 1 Jun 2026
Viewed by 298
Abstract
This review traces how our understanding of low- and intermediate-mass stars (hereafter LMS and IMS, respectively) evolved in time, in parallel with our knowledge of slow neutron-capture phenomena (the s-process). I shall focus in particular on the main component of this nucleosynthesis [...] Read more.
This review traces how our understanding of low- and intermediate-mass stars (hereafter LMS and IMS, respectively) evolved in time, in parallel with our knowledge of slow neutron-capture phenomena (the s-process). I shall focus in particular on the main component of this nucleosynthesis phenomenon, occurring in the above-mentioned stars close to the end of their lifetimes. They start ascending the Asymptotic Giant Branch (AGB), where both H- and He-shells exist, burning alternatively during the phases most relevant to our discussion: the so-called thermal pulses (hence, the name of TP-AGB stages for the final evolutionary period of these stars). I shall outline how such final stages were discovered to be a crucial source for neutron captures. Finally, I will briefly discuss what observational constraints and nuclear measurements have taught us about the status of our theoretical models in this field of nuclear and stellar physics. Full article
(This article belongs to the Special Issue Neutron Capture Processes in the Universe)
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18 pages, 6694 KB  
Review
The Laser Dazzling and Damage Effect on CCD: An Overview
by Qiheng Wei, Yongqiang Zhang, Wei Li, Fuli Tan, Lingyuan Wu, Zhaoning Li, Yanglong Li and Bo Fu
Photonics 2026, 13(6), 543; https://doi.org/10.3390/photonics13060543 - 1 Jun 2026
Viewed by 571
Abstract
The laser irradiation effect on Charge-Coupled Devices (CCDs) has attracted wide attention in photoelectric countermeasures and imaging system hardening. This review provides a systematic analysis of the phenomena and mechanisms of laser-induced dazzling and damage effects on CCD sensors. It summarizes experimental and [...] Read more.
The laser irradiation effect on Charge-Coupled Devices (CCDs) has attracted wide attention in photoelectric countermeasures and imaging system hardening. This review provides a systematic analysis of the phenomena and mechanisms of laser-induced dazzling and damage effects on CCD sensors. It summarizes experimental and theoretical research progress with continuous-wave (CW), pulsed, and composite lasers, revealing distinct interaction mechanisms such as thermal effects, dielectric breakdown, and plasma ablation. The review also covers quantitative evaluation methods for assessing laser irradiation effects. This work provides a comprehensive reference for future studies. Full article
(This article belongs to the Section Lasers, Light Sources and Sensors)
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23 pages, 19374 KB  
Review
Dynamics of Exploding Solitons in Mode-Locked Fiber Lasers
by Mário F. S. Ferreira and Sofia C. V. Latas
Fibers 2026, 14(6), 64; https://doi.org/10.3390/fib14060064 - 28 May 2026
Viewed by 718
Abstract
Many non-equilibrium phenomena and nonlinear dissipative systems can be described by the complex Ginzburg–Landau equation (CGLE). So far, several types of solutions to the cubic–quintic CGLE have been obtained, which can be mainly classified into two categories: stationary solutions and pulsating solutions. One [...] Read more.
Many non-equilibrium phenomena and nonlinear dissipative systems can be described by the complex Ginzburg–Landau equation (CGLE). So far, several types of solutions to the cubic–quintic CGLE have been obtained, which can be mainly classified into two categories: stationary solutions and pulsating solutions. One of the most striking forms of pulsating solutions is the exploding soliton, which belongs to the class of chaotic solutions. In this paper, we review the main properties of exploding solitons, considering the case of passively mode-locked fiber lasers described by the CGLE. The impact of the filter’s spectral response and the possibility of converting exploding solitons into fixed-shape pulses by using a proper combination of some higher-order effects are illustrated. An overview of recent experimental observations concerning exploding solitons in different laser configurations is also provided. Full article
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21 pages, 10575 KB  
Article
Analysis of Common-Source CoolMOS FETs-Based Bidirectional Switch Gate Driver for Vienna Rectifier Application
by Petr Cyprich, Pavel Cyprich, Jan Strossa, Vladislav Damec, Martin Sobek and Marcin Zygmanowski
Energies 2026, 19(11), 2593; https://doi.org/10.3390/en19112593 - 27 May 2026
Viewed by 256
Abstract
The rapid growth of electromobility and the increasing deployment of EV chargers emphasize the importance of pulse rectifiers with built-in power factor correction (PFC) filters. The new switching power devices offer higher converter switching frequencies, which enable a decrease in nominal values of [...] Read more.
The rapid growth of electromobility and the increasing deployment of EV chargers emphasize the importance of pulse rectifiers with built-in power factor correction (PFC) filters. The new switching power devices offer higher converter switching frequencies, which enable a decrease in nominal values of passive components, such as inductors and capacitors, and their physical dimensions. Devices like CoolMOS and GaN enable operation with low switching power, but are usually constructed for lower drain-source voltage. From this point of view, the Vienna Rectifier is a prospective type of pulse rectifier with built-in PFC because of its reduced blocking-voltage requirements for the power transistors. Nevertheless, faster switching semiconductor devices with lower switching gate charge require more precise driving circuit tuning and setup. There are many scientific papers focused on the driving setup and techniques of the power transistors applied in H-bridge topologies. The purpose of this paper is to investigate the commutation loop and the related switching phenomena of the Vienna Rectifier topology. This paper evaluates the driver setup for a CoolMOS-based Vienna Rectifier with anti-serial connection of transistors forming a bidirectional switch. The switching transients are analyzed and simulated. Subsequently, the real driver settings are evaluated on the real prototype. Full article
(This article belongs to the Special Issue Recent Advances in Design and Verification of Power Electronics)
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31 pages, 3749 KB  
Review
Design Considerations for Low-Temperature Plasma Production in Air Using Pulsed Dielectric Barrier Discharges: A Review
by Luutzen Franciscus Ate Wymenga, Jan van Turnhout, Mohamad Ghaffarian Niasar, Henk van Zeijl, Willem Dirk van Driel and Guoqi Zhang
Plasma 2026, 9(2), 15; https://doi.org/10.3390/plasma9020015 - 14 May 2026
Viewed by 989
Abstract
Low-temperature atmospheric plasma (LTP) is widely used in industrial processes, such as disinfection, surface modification and wastewater treatment. The dielectric barrier discharge (DBD) is regarded as one of the most robust and reliable methods for generating LTP in ambient air. Compared to conventional [...] Read more.
Low-temperature atmospheric plasma (LTP) is widely used in industrial processes, such as disinfection, surface modification and wastewater treatment. The dielectric barrier discharge (DBD) is regarded as one of the most robust and reliable methods for generating LTP in ambient air. Compared to conventional AC excitation, pulsed powering offers several advantages (i.e., lower energy use and heat production). The present trend is to use short and fast pulses (in the nano- and picosecond range). In this review, the key design parameters of a DBD (barrier thickness, relative permittivity and gap distance) are discussed. Material-specific phenomena like surface charging and degradation are analyzed. The complex interactions between the pulse source and DBD are examined. By mapping the interdependencies, this review aims to support the rational design and optimization of pulsed DBD systems, and to facilitate their broader industrial use. Full article
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21 pages, 7147 KB  
Article
Exact Wave Structures and Modulation Instability in the Fokas System
by Nadiyah Hussain Alharthi and Melike Kaplan
Symmetry 2026, 18(4), 650; https://doi.org/10.3390/sym18040650 - 13 Apr 2026
Viewed by 438
Abstract
The analytically integrable Fokas system, arising under the slowly varying envelope approximation for weakly nonlinear and weakly dispersive quasi-monochromatic waves, is used to describe pulse propagation in single-mode optical fibers and is investigated here through symbolic computational techniques. This paper establishes multiple families [...] Read more.
The analytically integrable Fokas system, arising under the slowly varying envelope approximation for weakly nonlinear and weakly dispersive quasi-monochromatic waves, is used to describe pulse propagation in single-mode optical fibers and is investigated here through symbolic computational techniques. This paper establishes multiple families of exact wave solutions through the combined use of the modified simple equation strategy and the generalized exponential rational function technique. These analytical approaches enable the derivation of diverse solitary and periodic wave structures characterized by adjustable parameters that control the amplitude, shape, and propagation dynamics of the waveform. To demonstrate the physical significance of the derived solutions, comprehensive graphical visualizations are provided, highlighting symmetric propagation features and diverse parameter-dependent behaviors of the wave structures. The flexibility of the obtained solution structures allows for a detailed examination of parameter-dependent wave dynamics and waveform evolution within the considered model. Moreover, a detailed modulation instability analysis is carried out to investigate the stability characteristics of continuous-wave solutions in the context of the Fokas system. The results identify parameter regimes associated with stable and unstable wave propagation, thereby enhancing the understanding of nonlinear instability phenomena in integrable optical models. In general, the study contributes new analytical wave structures, stability interpretations, and parametric insights that extend the applicability of the Fokas system in nonlinear wave theory and optical physics. Full article
(This article belongs to the Section Physics)
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15 pages, 2320 KB  
Article
Electromagnetic Control of Ferromagnetic Particle Movement Using PID and PWM
by Jesús Alexis Salcedo Muciño, Juan Alejandro Flores Campos, Adolfo Angel Casares Duran, Juan Carlos Paredes Rojas, José Juan Mojica Martínez and Christopher René Torres-SanMiguel
Magnetochemistry 2026, 12(4), 48; https://doi.org/10.3390/magnetochemistry12040048 - 10 Apr 2026
Viewed by 988
Abstract
In this article, the motion control of ferromagnetic particles through varying a non-invasive magnetic field is addressed. Within an experimental test bench, three experiments are proposed to verify motion control, which consist of control of the distance between electromagnets, retention of particles over [...] Read more.
In this article, the motion control of ferromagnetic particles through varying a non-invasive magnetic field is addressed. Within an experimental test bench, three experiments are proposed to verify motion control, which consist of control of the distance between electromagnets, retention of particles over the flow, and manipulation of the direction of particle flow at a “Y”-type bifurcation emulating an “OR” gate. At each experimental stage, instrumented test benches were integrated with current, distance, and flow sensors, enabling measurement and feedback of the system’s physical variables. These benches were configured using pulse-width-modulation (PWM) and Proportional–Integral–Derivative (PID) controllers to regulate the current supplied to the electromagnets and, thereby, control the intensity of the induced electromagnetic field according to the requirements of each experiment. Different study cases were defined to analyze the operational limits of the system by varying the current influencing the electromagnetic field and the configuration of the electromagnets. The results describe the response of the magnetic field, the induced force, and the behavior of the suspended particles under each condition, providing elements to characterize the performance of the electromagnetic system in operational scenarios and contributing to the understanding of the phenomena associated with the non-invasive manipulation of ferromagnetic particles by means of controlled magnetic fields. Full article
(This article belongs to the Topic Magnetic Nanoparticles and Thin Films)
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