Double Resonance Modes Research Articles

Broadband metamaterial absorber with double resonant modes using single-layer substrate

A novel broadband metamaterial absorber (MA) is proposed in this paper. The element of absorber consists of square substrate, top and bottom metal layer. A circular patch is printed on the top layer and located in the center of element. Other three circular patches are located in three corners and connected with the center patch, respectively. The mechanism is analysed and discussed with the equivalent circuit and parameter study. It exhibits double resonant frequencies corresponding to different working modes and achieves broadband of good absorption. The structure has a thickness of 1.0 mm and two resonate frequencies of 7.94 GHz and 8.65 GHz. The experiment results are good agreement with the simulated ones. The simple structure shows a relative bandwidth of 19%, polarization insensitive and wide operating angle. The proposed absorber can be widely applied in national defence and civil fields due to its simple structure and good absorption characteristic.

Active tunable terahertz resonators based on hybrid vanadium oxide metasurface

Hybrid terahertz (THz) metamaterial resonators have exhibited superior reconfigurable resonant response enabled by active materials, such as liquid crystals, graphene, and semiconductors. However, the tunable range of constitutive parameters of materials is still limited, which leads to the low modulation depth of THz devices. Unlike other phase change materials, vanadium dioxide (VO2) exhibits an insulator-to-metal transition characteristic and the conductivity can be increased by 4–5 orders of magnitude under external stimulus including electric fields, optical, and thermal pumps. Here, we propose an active tunable THz resonator based on a hybrid VO2 metasurface for thermal control. The simulated results show that by external thermal stimulation, we realize the tuning between the single and double resonant modes. The resonant peak at high frequency disappears while the low frequency peak is enhanced with the increasing temperature. The simulated surface electric fields confirm the physical mechanism of the excellent tunable performance that the L-shaped and cross resonances play a dominant role at the low and high temperature, respectively, due to the VO2 phase transition. Such a hybrid VO2 metasurface resonator with tunable characteristics will greatly promote the practical application of THz functional devices, such as modulators, sensors and filters.

An Antenna With a Stair-Like Ground Branch for Octa-Band Narrow-Frame Mobile Phone

An antenna with a small nonground portion (56 × 5 mm2) for 5.7 in octa-band mobile phones is presented in this letter. Owing to the stair-like ground branch, the width of the nonground portion is 5 mm (0.013 λg at frequency 0.8 GHz), and the area of ground clearance is only 280 mm2 . By utilizing the space with a small value of the electric field, the antenna's size can be reduced without worsening the performance. The optimized structure can generate the high band that covers GSM1800, GSM1900, UMTS, LTE2300, and LTE2500 bands (1710–2690 MHz). Moreover, a double-resonant mode is generated in the low band for LTE700, GSM850, and GSM900 bands (704–960 MHz). A prototype is fabricated, and the measured −6 dB impedance bandwidths are 310 MHz (690–1000 MHz) and 1270 MHz (1680–2950 MHz). Meanwhile, the measured patterns, efficiencies, and gains are also obtained. This antenna is promising to utilize in the future.

Development and Implementation of a PIN-Diode Controlled, Quadrature-Enhanced, Double-Tuned RF Coil for Sodium MRI.

Sodium (23Na) MRI provides complementary cellular and metabolic information. However, the intrinsic MR sensitivity of 23Na is considerably lower compared with that of the proton, making it difficult to measure MR-detectable sodium signals. It is therefore important to maintain the signal-to-noise ratio (SNR) of the sodium signal as high as possible. Double-tuned coils are often employed in combinationwith a 1H coil, providing structural images and B0 shimming capability. The double-tuned coil design can be achieved with the use of two geometrically decoupled coils whose B1 field directions are perpendicular to each other. This can be used to design quadrature-driven, single-nucleus coils to improve SNR, and additionally, this coil can also be utilized as a linear-driven double-resonant mode. Here, we have developed and evaluateda quadrature-enhanced, double-tuned coil. The novel coil uses PIN-diode switches, inserted only in the loop coil, to shift the resonance frequency between 1H and 23Na so that 23Na signals can be acquired in quadrature and the capability of using 1H function remains. Consequently, the 23Na SNR values obtained with the double-tuned coil are nearly 33% and 17% higher in comparison with geometrically identical single-tuned coils. SNR plots also show the superiority of double-tuned coil in 23Na.

Synchronous Tuning of Twined Resonance Modes with Controllable Spectral Separation in Plasmonic Gratings

We investigated angle-resolved tuning performance of the double resonance modes of waveguide metallic grating structures, where the incident angle was changed in the plane formed by the extending direction of the grating lines and the wave vector with the grating plane tilted with respect to the vertical axis. Double resonance modes were observed due to tilting of the grating, which were tuned simultaneously to the blue with increasing the angle of incidence. The spectral separation between the resonance modes can be adjusted simply by changing the tilting angle of the grating. Such a double resonance device is important for exploring multichannel optical filters, optical switching device, or sensors.

Ultraviolet Raman spectra of double-resonant modes of graphene

Ultraviolet (UV) Raman spectroscopy is a powerful technique for applications in fundamental and applied sciences of condensed matter and material science. To investigate double-resonant Raman scattering processes of graphene, we study the characteristic 2D Raman mode profiles of 1–4 layer graphene (supported and suspended) and graphite using both UV and visible excitation lasers at room temperature. At UV excitation energy of 3.81 eV, we observe that three scattering processes contribute dominantly to 2D mode profiles, which is a general feature for all graphene samples, showing the intensity diminishing of other scattering processes as theoretically predicted. We also find the asymmetric G∗ double resonant mode is sensitive to the high incident laser energy, and I(G)/I(2D) of monolayer graphene is most sensitive to UV laser energy due to near off resonant behavior of 2D modes at high excitation energy. Our results provide direct experimental evidences to further understand double-resonance scattering mechanism of few layer graphene.

Electrophoretic stabilization of freestanding pristine graphene foams with carbon nanotubes for enhanced optical and electrical response

Graphene materials, including three-dimensional foams, are commonly transferred from growth substrates using polymer stabilization processes. Even after harsh chemical and annealing treatments to remove the polymer, residues remain which compromise the electronic, thermal, gravimetric, and chemical properties of the graphene. To overcome this, we present a scalable, clean approach to stabilize graphene foams by conformal electrophoretic deposition of web-like networks of surfactant-free single-walled carbon nanotubes directly from polar solvents. We demonstrate these coatings to yield a pristine stabilized graphene material exhibiting 50x lower electrical resistance and a 10cm−1 optical red-shift in the Raman G′ double resonance mode in comparison to polymer-stabilized graphene. This approach enables the formation of three-dimensional architectures of nanomaterials without the adverse effects associated with residual impurities from polymer and chemical processing.

Note: On the generation of sub-300 keV flash-X-rays using rod-pinch diode: an experimental investigation.

Generation of flash X-rays (FXRs) at less than 500 keV is described with emphasis on experimental investigation. The pulser is a Tesla transformer-Water transmission line based pulsed power generator operating in double resonance mode to power a rod-pinch diode. The configuration of aspect ratio reported here falls much below the normally reported ratios for the rod-pinch diode operation. Experimental investigation at such low pulsed voltage has revealed "flowering" of the anode tip and "pitting" of the perspex window. A possible explanation in terms of Lorentz body force is discussed rather than the pinch mechanism generally suggested in literature. The experimental investigation for the FXR generation is corroborated by measuring the radiation dose using CaSO4 (Dy) thermo luminescent dosimeters.

Small-Size Multiresonant Octaband Antenna for LTE/WWAN Smartphone Applications

A compact multiresonant antenna for octaband LTE/WWAN operation in the internal smartphone applications is proposed and discussed in this letter. With a small volume of 15×25×4 mm <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">3</sup> , the presented antenna comprises two direct feeding strips and a chip-inductor-loaded two-branch shorted strip. The two direct feeding strips can provide two resonant modes at around 1750 and 2650 MHz, and the two-branch shorted strip can generate a double-resonance mode at about 725 and 812 MHz. Moreover, a three-element bandstop matching circuit is designed to generate an additional resonance for bandwidth enhancement of the lower band. Ultimately, up to five resonances are achieved to cover the desired 704-960- and 1710-2690-MHz bands. Simulated and measured results are presented to demonstrate the validity of the proposed antenna.

Cryogenic Ion Chemistry and Spectroscopy

The use of mass spectrometry in macromolecular analysis is an incredibly important technique and has allowed efficient identification of secondary and tertiary protein structures. Over 20 years ago, Chemistry Nobelist John Fenn and co-workers revolutionized mass spectrometry by developing ways to non-destructively extract large molecules directly from solution into the gas phase. This advance, in turn, enabled rapid sequencing of biopolymers through tandem mass spectrometry at the heart of the burgeoning field of proteomics. In this Account, we discuss how cryogenic cooling, mass selection, and reactive processing together provide a powerful way to characterize ion structures as well as rationally synthesize labile reaction intermediates. This is accomplished by first cooling the ions close to 10 K and condensing onto them weakly bound, chemically inert small molecules or rare gas atoms. This assembly can then be used as a medium in which to quench reactive encounters by rapid evaporation of the adducts, as well as provide a universal means for acquiring highly resolved vibrational action spectra of the embedded species by photoinduced mass loss. Moreover, the spectroscopic measurements can be obtained with readily available, broadly tunable pulsed infrared lasers because absorption of a single photon is sufficient to induce evaporation. We discuss the implementation of these methods with a new type of hybrid photofragmentation mass spectrometer involving two stages of mass selection with two laser excitation regions interfaced to the cryogenic ion source. We illustrate several capabilities of the cryogenic ion spectrometer by presenting recent applications to peptides, a biomimetic catalyst, a large antibiotic molecule (vancomycin), and reaction intermediates pertinent to the chemistry of the ionosphere. First, we demonstrate how site-specific isotopic substitution can be used to identify bands due to local functional groups in a protonated tripeptide designed to stereoselectively catalyze bromination of biaryl substrates. This procedure directly reveals the particular H-bond donor and acceptor groups that enforce the folded structure of the bare ion as well as provide contact points for noncovalent interaction with substrates. We then show how photochemical hole-burning involving only vibrational excitations can be used in a double-resonance mode to systematically disentangle overlapping spectra that arise when several conformers of a dipeptide are prepared in the ion source. Finally, we highlight our ability to systematically capture reaction intermediates and spectroscopically characterize their structures. Through this method, we can identify the pathway for water-network-mediated, proton-coupled transformation of nitrosonium, NO(+) to HONO, a key reaction controlling the cations present in the ionosphere. Through this work, we reveal the critical role played by water molecules occupying the second solvation shell around the ion, where they stabilize the emergent product ion in a fashion reminiscent of the solvent coordinate responsible for the barrier to charge transfer in solution. Looking to the future, we predict that the capture and characterization of fleeting intermediate complexes in the homogeneous catalytic activation of small molecules like water, alkanes, and CO2 is a likely avenue rich with opportunity.

Low-Profile Printed Octa-Band LTE/WWAN Mobile Phone Antenna Using Embedded Parallel Resonant Structure

A simple low-profile antenna for octa-band LTE/WWAN operation in the internal mobile phone application is proposed and studied in this article. Consisting of a feeding strip and a coupling strip mainly, the presented antenna can be easily printed on the no-ground area of the top of a FR4 substrate, yet it occupies only a size of 15 × 40 mm <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sup> and has a height of 3.5 mm. In this scheme, a chip inductor (L <sub xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">1</sub> = 20 nH) is loaded in the long inductive strip, which can form a parallel resonant structure together with the coupling strip section close to the feeding strip. With these presences, a double-resonance mode (λ/4 resonant mode) is successfully generated at about 720 and 900 MHz to cover the lower band of LTE700/GSM850/900 (704-960 MHz). While the desired upper band of DCS1800/PCS1900/UMTS2100/LTE2300/2500 (1710-2690 MHz) can be obtained with the help of second two resonant modes, including a high-order λ/2 resonant mode at 1800 MHz and a λ/4 resonant mode at 2550 MHz. That is to say that those two wide operating bandwidths are achieved to cover all the octa-band LTE/WWAN operation. Good radiation efficiency and antenna gain for frequencies over the desired operating bands is obtained. Detailed design considerations of the proposed antenna are described, and both experimental and simulation results are also presented and discussed.

Nonlinear alfvénic fast particle transport and losses

Magnetohydrodynamic instabilities like Toroidal Alfvén Eigenmodes or core-localized modes such as Beta Induced Alfvén Eigenmodes and Reversed Shear Alfvén Eigenmodes driven by fast particles can lead to significant redistribution and losses in fusion devices. This is observed in many ASDEX Upgrade discharges. The present work aims to understand the underlying resonance mechanisms, especially in the presence of multiple modes with different frequencies. Resonant mode coupling mechanisms are investigated using the drift kinetic HAGIS code [Pinches 1998]. Simulations were performed for different plasma equilibria, in particular for different q profiles, employing the availability of improved experimental data. A study was carried out, investigating double-resonant mode coupling with respect to various overlapping scenarios. It was found that, depending on the radial mode distance, double-resonance is able to enhance growth rates as well as mode amplitudes significantly. Small radial mode distances, however can also lead to strong nonlinear mode stabilization of a linear dominant mode.With the extended version of HAGIS, losses were simulated and directly compared with experimental loss measurements. The losses' phase space distribution as well as their ejection signal is consistent with experimental data. Furthermore, it allowed to characterize them as prompt, resonant or stochastic. It was found that especially in multiple mode scenarios (with different mode frequencies), abundant incoherent losses occur in the lower energy range, due to a broad phase-space stochastization. The incoherent higher energetic losses are "prompt", i.e. their initial energy is too large for confined orbits.

Size dependence of static and dynamic magnetic properties in nanoscale square Permalloy antidot arrays

Permalloy antidot arrays with different square hole sizes (1200×1200, 800×800, and 400×400nm2) have been fabricated by means of electron-beam lithography and lift-off techniques. The smaller square hole size results in enhanced remanence and reduced coercivity in the antidot array. Multiple resonance modes were clearly observed for the magnetic field applied normal to the array plane, and double uniform resonance modes occurred when the field deviated more than 30° from the normal to the plane. Two distinct dipolar field patterns with different orientations and magnitudes split the uniform resonance into double resonance modes. The double resonance modes show uniaxial in-plane anisotropy and the easy axes are orthogonal. The magnitude of the induced dipolar anisotropy remains almost constant with changes in the square hole size. The double resonance peaks move to low field with reduction of the square hole size.

Rectangular-Plate-Type Piezoelectric Ceramics Ultrasonic Motor Using Double 1st Resonance Modes of Longitudinal and Width-Bending Vibrations

This paper deals with a piezoelectric ceramics ultrasonic motor of rectangular plate type using double resonance modes of longitudinal (L1) and width-bending (B1) vibrations. First, the motor construction and its operating principle are described, and second, the measured characteristics of this prototype motor are presented.

Comparison between Double-Resonant and Non-Resonant Mode Driven Convections in a Stellarator with a Non-Monotonic Rotational Transform

For a stellarator (or tokamak) with a non-monotonic rotational transform, both the double-resonant and non-resonant interchange type modes become unstable, when the magnetic curvature is unfavorable in a finite region including the zero magnetic shear surface r = r s . These modes generate convective motions and poloidal shear flows. The non-resonant mode driven convection affects the r ≃ r s region significantly, although a decrease of central density is seen. On the other hand, the double-resonant mode driven convection affects the central region for a peaked density profile and a stair-like decrease of the central density is seen. The evolution of the density profile is also correlated with the behavior of the nonlinearly generated poloidal flow.

Beam extraction from a compact Ku-band electron cyclotron resonance ion source with double resonance modes

Beam extraction tests were carried out using a new compact Ku-band electron cyclotron resonance (ECR) ion source. In the case of a single rf frequency operation, a B2 zone can contribute for increase of single and low charged state ion beams when the gas flow rate is relatively higher than that for the basic ECR mode. The scheme seems, however, not so effective for the production of multicharged state ion beams. A double frequency heating (12 and 14 GHz) is, on the other hand, effective for increase of extracted ion current when the rf power is injected into the chamber from both the axial and the radial ports, as succeeded at the LBL experiment.

A Study of Vibratory Gyroscope using Membrane Structure as A Spring

Recently, micromachined vibratory gyroscopes are in the lime light. Especially, the double resonant mode is important in order to improve the sensitivity of micro gyroscopes. For such a purpose, some membrane structure of the micromachined gyroscopes have been reported. In this paper, we show the design strategy of the membrane spring for noting the resonance characteristics. In the paper, by measuring the fabricated devices and some simulations, we pointed out that the through knowledge of a nonlinearity of the membrane spring is important for micro structures.

Generation of multiple pulses with extremely short pulse repetition interval

A new type of multipulse generator is proposed for the generation of high power pulses with an extremely short interpulse repetition interval. In this system, an air-core step-up transformer is used with a magnetic switch and a pulse forming line, which is charged in the double-resonance mode. Numerical simulations of this system have shown that 600 kV, 56 ns pulses, matched to a 20 /spl Omega/ impedance can be produced with a minimum pulse separation of 2.7 /spl mu/s. A small system was constructed to demonstrate the production of double pulses experimentally. The system contains two first stage capacitors of 150 nF each, a 1:15 air-core step-up transformer, a magnetic switch using cobalt based material, a second stage capacitor of 1.6 nF, and an 80 /spl Omega/ load. Double-pulses 100 ns wide, peak voltages of 85 kV (first pulse) and 90 kV (second pulse) have been successfully generated with an interval of 3.75 /spl mu/s between pulses, when the first stage capacitors were charged to 14 kV (for the first pulse) and 17 kV (for the second pulse).

Driving Technique of Reference Vibration for Vibratory Gyroscopes using Hard Spring Effect

Recently, many micromachined vibratory gyroscopes are proposed. Almost all the devices have been made efforts to obtain the double resonant mode in order to improve the sensitivity of micro gyroscopes. Nevertheless, there are some difficulty to obtain the accurate structure for consistent resonant frequencies between reference vibration and detection vibration in fabrication steps. In this paper, we show the design strategy of the high sensitive vibratory gyroscope using the hard spring effect positively. We propose the method for adjusting vibrating frequency and show the example of the actual device and some measured data for high performance devices.

A pulsed power system for generating multiple high voltage pulses with a short pulse repetition interval

A new type of multipulse generator is proposed for the generation of high power pulses with extremely short pulse repetition interval. In this system, an air-core step-up transformer is used with a magnetic switch and the pulse forming line is charged on a double resonance mode. Numerical simulations of the system have shown that 56 ns duration pulses matched to a 20 Ω impedance can be produced with a minimum pulse separation of 2.7 μs. The voltages and the efficiencies of the output pulses are 0.63 MV and 93% for the first pulse and 0.56 MV and 69% for the second pulse.