Your search keyword '"microwave cavity"' showing total 3,444 results

1. Adiabatic elimination in the presence of multiphoton transitions in atoms inside a cavity.

Author

Maity, Prosenjit

Abstract

Various approaches have been used in the literature for eliminating nonresonant levels in atomic systems and deriving effective Hamiltonians. Important among these are elimination techniques at the level of probability amplitudes, operator techniques to project the dynamics on to the subspace of resonant levels, Green’s function techniques, the James’ effective Hamiltonian approach, etc. None of the previous approaches is suitable for deriving effective Hamiltonians in intracavity situations. However, the James’ approach does work in the case of only two-photon transitions in a cavity. A generalization of the James’ approach works in the case of three-photon transitions in a cavity, but only under Raman-like resonant conditions. Another important approach for adiabatic elimination is based on an adaptation of the Markov approximation well-known in the theory of system–bath interactions. However, this approach has not been shown to work in intracavity situations. In this paper, we present a method of adiabatic elimination for atoms inside cavities in the presence of multiphoton transitions. We work in the Heisenberg picture, and our approach has the advantage that it allows one to derive effective Hamiltonians even when Raman-like resonance conditions do not hold. [ABSTRACT FROM AUTHOR]

Published

2024

2. Crystal Silicon Photoconductivity with Amorphous Inclusions.

Author

Babychenko, Oksana, Sushko, Olha, Babychenko, Serhii, Logunov, Volodymyr, and Bendeberya, Hennadii

Subjects

AMORPHOUS silicon, SILICON crystals, SEMICONDUCTOR materials, PHOTOCONDUCTIVITY, GAMMA rays, SILICON solar cells

Abstract

The results of the numerical-analytical modeling of the photoconductivity of crystalline silicon with the inclusion of amorphous silicon are presented. These ones can be used in studying the principles of a new class of photovoltaic converters based on modified semiconductor materials. The initial data for such a model should be experimentally obtained layer parameters. During the calculations, it was assumed that the change in photoconductivity is caused by a change in the degree of disorder of amorphous inclusions. It was assumed that the semiconductor structure is dominated by cylindrical inclusions and the degree of sample disorder γ varies in the range from 0.040 to 0.065. That is, approximately 5 % of amorphous inclusions in the volume of the crystalline structure. The paper presents the results of calculations of changes in photoconductivity depending on the degree of disorder of the semiconductor structure. The results are in good agreement with obtained experimental data on amorphous-crystalline structures formed as a result of irradiation by γ-quanta. The photoconductivity of semiconductor samples irradiated with gamma rays was studied by microwave photomodulation methods using a resonator measuring transducer. [ABSTRACT FROM AUTHOR]

Published

2024

3. Strong indirect coupling of a magnet with a piezoelectric in a microwave cavity

Author

Parisa Maleki and babak zare

Subjects

microwave cavity, magnetic material, piezoelectric material, strong coupling, Physics, QC1-999

Abstract

A system consisting of a magnetic material and a piezoelectric material placed within a microwave cavity is considered. The strong and long-range coupling between the piezoelectric material and the magnetic material mediated by the microwave cavity has been studied. We have shown that the realization of the strong coupling regime is not only possible between each of these materials with the microwave cavity, but also between the magnetic material and the piezoelectric material.

Published

2023

4. Microwave-cavity-based Online Moisture Sensing for Concrete Fabrication.

Author

Kexin Liu, Yipeng Zhang, Weiguang Wang, Xuebin Cheng, and Ziyi Weng

Abstract

Moisture content is critical to concrete fabrication. Currently, concrete fabrication often involves experienced workers who can gauge whether the water volume is sufficient. This active human involvement requires appearance or thickness checks, which is not suitable for mass production. This method cannot also tell the actual moisture content. Moreover, different workers may give different assessments for the same concrete, which may further lead to different strengths of concrete. Thus, we propose and design a microwave-cavity-based online moisture sensing system to monitor concrete fabrication. Our system utilizes a microwave resonator as a front-end sensor to monitor moisture. This resonator is sensitive to the dielectric coefficient of a particular object. This dielectric coefficient of concrete notably changes when the water yield varies and hence can be readily detected. With this sensitive resonator, we built an online moisture-sensing system. Our prototype achieves moisture sensing with an error of as low as 0.5% and can check moisture content twice a second. [ABSTRACT FROM AUTHOR]

Published

2023

5. Kerr-Nonlinearity-Triggered Nonclassicality of Magnons in a Photon-Magnon Coupling System.

Author

Jiang, Xi, Tang, Shiqing, and Li, Songsong

Subjects

MAGNONS, YTTRIUM iron garnet, CAVITY resonators, QUANTUM electrodynamics, QUANTUM information science

Abstract

Hybrid quantum systems have attracted much attention due to the fact that they combine the advantages of different physical subsystems. Cavity QED (cavity quantum electrodynamics) with magnons is a hybrid quantum systems that combines a YIG (Yttrium Iron Garnet) sphere and a 3D (three-dimensional) rectangular microwave cavity. Based on this hybrid photon-magnon system, we obtain an approximate analytic solution by the RWA (rotating wave approximation) with an ingenious transformation. After skillfully diagonalizing the Hamiltonian, we show that the Kerr-nonlinearity interactions could yield a negativity value of the Wigner function, periodic quadrature squeezing effects, antibunching property, and field nonclassicality in the magnon. Our work may stimulate the study of nonclassicality of photon-magnon coupling systems and its potential applications in quantum information processing. [ABSTRACT FROM AUTHOR]

Published

2022

6. Cavity magnonics.

Author

Zare Rameshti, Babak, Viola Kusminskiy, Silvia, Haigh, James A., Usami, Koji, Lachance-Quirion, Dany, Nakamura, Yasunobu, Hu, Can-Ming, Tang, Hong X., Bauer, Gerrit E.W., and Blanter, Yaroslav M.

Subjects

*CAVITY resonators, *BRILLOUIN scattering, *QUASIPARTICLES, *OPTICAL resonators, *ELECTROMAGNETIC fields, *QUBITS

Abstract

Cavity magnonics deals with the interaction of magnons — elementary excitations in magnetic materials — and confined electromagnetic fields. We introduce the basic physics and review the experimental and theoretical progress of this young field that is gearing up for integration in future quantum technologies. Much of its appeal is derived from the strong magnon–photon coupling and the easily-reached nonlinear regime in microwave cavities. The interaction of magnons with light as detected by Brillouin light scattering is enhanced in magnetic optical resonators, which can be employed to cool and heat magnons. The microwave cavity photon-mediated coupling of a magnon mode to a superconducting qubit enables measurements in the single magnon limit. [ABSTRACT FROM AUTHOR]

Published

2022

7. Tunable High-Q Photonic Bandgap Cavity

Author

Agrawal, Ankur, Dixit, Akash V., Schuster, David I., Chou, Aaron, Carosi, Gianpaolo, editor, and Rybka, Gray, editor

Published

2020

8. Multiple-Cell Cavity for High Mass Axion Dark Matter Search

Author

Jeong, Junu, Youn, SungWoo, Semertzidis, Yannis K., Carosi, Gianpaolo, editor, and Rybka, Gray, editor

Published

2020

9. Axion Dark Matter Search at IBS/CAPP

Author

IBS/CAPP, Youn, SungWoo, Carosi, Gianpaolo, editor, and Rybka, Gray, editor

Published

2020

10. Ag/SeO2/C Avalanche Type Resonant Tunneling Schottky Barriers

Author

Sabah E. Al Garni, A.F. Qasrawi, and Najla M. Khusayfan

Subjects

Ag/SeO2/C, tetragonal, microwave cavity, Esaki diodes, negative conductance, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Abstract Herein, the design and characterization of Ag/SeO2/C avalanche type resonant tunneling devices are reported. Thin pellets of SeO2 nano-powders pressed under hydraulic pressure of 1.0 MPa which is used as the active material are characterized. They showed tetragonal structure refereeing to space group of P 4 2 m b c and lattice parameters of a = b = 7.866 Å and c =5.336 Å. The current-voltage characteristic curves have shown that SeO2 can perform as active media to produce resonant tunneling diodes when forward biased and as avalanche type diode when reverse biased. The peak to valley current ratios of these diodes reached 18.3. In addition, the impedance spectroscopy measurements have shown that the device works in the low impedance mode when operated in the microwave range of frequency near 1.50 GHz. Negative conductance effect is observed in that frequency domain. The features of the Ag/SeO2/C nominate them for use as signal amplifiers and microwave oscillators.

Published

2022

11. Design and operational experience of a microwave cavity axion detector for the 20–100μeV range

Author

Zhong, L. [Yale Univ., New Haven, CT (United States)]

Published

2017

12. Dual-mode rectangular microwave cavity for precision spectroscopy of hyperfine structure in muonium.

Author

Iwai, R., Fukumura, S., Fushihara, M., Goto, Y., Kanda, S., Nishimura, S., Strasser, P., Shimomura, K., Tada, H., Tanaka, K.S., and Torii, H.A.

Subjects

*CAVITY resonators, *PARTICLE physics, *MAGNETIC flux density, *MAGNETIC field measurements, *HYPERFINE structure, *MAGNETIC structure, *MICROWAVE spectroscopy

Abstract

Precision microwave spectroscopy of the ground-state hyperfine structure in muonium provides a stringent test of the Standard Model in particle physics. The MuSEUM collaboration is preparing for such a measurement, aiming for precision down to ≈ 1 ppb, utilizing the world's most intense pulsed muon beam at J-PARC. The measurement of the Zeeman-split structure with an external magnetic field of 1.7 T also precisely determines the muon's magnetic moment (≈ 10 ppb). In the future, improved precision of the magnetic moment can be potentially obtained by measurements with different magnetic field strengths, however, it entails upgrading current cylindrical microwave cavities to rectangular ones. As the first step for the upgrade, we have developed a dual-mode rectangular cavity for the measurement with 2.9 T field. The electromagnetic design and production have been established, and frequency sweeping with two desired modes has been successfully demonstrated. Moreover, the overall performance of the measurement at 2.9 T field was evaluated with Monte Carlo simulations. These studies pave the way for a further extension of the MuSEUM experiment at various strengths of the magnetic fields. [ABSTRACT FROM AUTHOR]

Published

2024

13. Efficient discrete modelling of axisymmetric radiating structures

Author

Agunlejika, Oluwafunmilayo

Subjects

621.382, Antenna modelling, Axisymmetric radiating structures, Maxwell's equation, Microwave cavity, Slotted antenna, Transmission Line Modelling, Cylindrical TLM

Abstract

This thesis describes research on Efficient Discrete Modelling of Axisymmetric Radiating Structures . Investigating the possibilities of surmounting the inherent limitation in the Cartesian rectangular Transmission Line Modelling (TLM) method due to staircase approximation by efficiently implementing the 3D cylindrical TLM mesh led to the development of a numerical model for simulating axisymmetric radiating structures such as cylindrical and conical monopole antennas. Following a brief introduction to the TLM method, potential applications of the method are presented. Cubic and cylindrical TLM models have been implemented in MATLAB and the code has been validated against microwave cavity benchmark problems. The results are compared to analytical results and the results obtained from the use of commercial cubic model (CST) in order to highlight the benefit of using a cylindrical model over its cubic counterpart. A cylindrical TLM mesh has not previously been used in the modelling of axisymmetric 3D radiating structures. In this thesis, it has been applied to the modelling of both cylindrical monopole and the conical monopole. The technique can also be applied to any radiating structure with axisymmetric cylindrical shape. The application of the method also led to the development of a novel conical antenna with periodic slot loading. Prototype antennas have been fabricated and measured to validate the simulated results for the antennas.

Published

2016

14. Hydraulic pressure and temperature effects on the structural, morphological and electrical properties of SeO2 powders.

Author

Algarni, Sabah E., Qasrawi, A. F., and Khusayfan, Najla M.

Abstract

Herein, powders of SeO2 are subjected to hydraulic pressure in the range of 1.0–12 MPa and heating cycles in the range of 290–383 K. The pressure and temperature effects on the crystalline nature, plane orientations, structural parameters, surface morphology, composition, electrical resistivity, capacitance spectra and conductance spectra are explored. It is observed that hydraulic pressure value of 6.0 MPa is a critical value at which the tetragonal SeO2 grains prefer (020) plane orientation over (011) planes. The (020) plane orientations resulted in remarkable changes in the lattice parameters, structural parameters, electrical resistivity, capacitance and conductance spectra. In addition, the heating and cooling cycles of the samples pressed at 10 MPa have shown that the transition of the planes is permanent. The heated and cooled pellets displayed resonance–antiresonance in the capacitance spectra near 0.43 GHz. The resonance–antiresonance phenomena are accompanied with negative conductance effect near 0.43 GHz. The enhancements in the properties of SeO2 powders that are achieved via pressure and temperature effects make them appropriate for electronic circuit technological applications. [ABSTRACT FROM AUTHOR]

Published

2022

15. Effects of Si Slabs on the Performance of CdO Thin Films Designed for Optoelectronic Applications

Author

Sabah E. AlGarni and A.F. Qasrawi

Subjects

CdO/Si/CdO, high absorbance, optical conductivity, microwave cavity, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Herein, the structural, morphological, optical and electrical properties of CdO stacked layers comprising Si slabs of thickness of 100 nm are investigated. The performance of the stacked layers, which are prepared by the thermal evaporation technique under vacuum pressure of 10-5 mbar, is remarkably enhanced via insertion of Si thin slabs. The presence of Si slabs between the layers of CdO improves the crystallinity and surface morphology, increases the light absorbability in the ultraviolet and visible ranges of light and also increases the dielectric constant, the quality factor, and optical conductivity values. The optical conductivity parameters, which are analyzed in accordance with Drude-Lorentz approach, have shown that the insertion of the Si layers rises the values of the drift mobility of holes in CdO and lowers the free holes concentration. The energy band gap of CdO films is narrowed from 2.20 to 1.27 eV upon insertion of Si slabs. The applicability of the plasmonic CdO/Si/CdO devices as low pass filers in the frequency domain of 0.01-1.80 GHz is verified through impedance spectroscopy measurements.

Published

2022

16. Ultrathin, Electrically Small Noise Suppression Sheet for Microwave Cavities of 3-D Integrated Circuits: Design Methodology and Realization.

Author

Yi, Da, Tang, Liu, Tang, Ming-Chun, Wei, Xing-Chang, and Li, Er-Ping

Subjects

*INTEGRATED circuit design, *THREE-dimensional integrated circuits, *CAVITY resonators, *PARALLEL-plate waveguides, *FLEXIBLE electronics

Abstract

Miniaturized microwave cavities constructed by the parallel-plate waveguide (PPW) becomes one of the main propagation pathways of the radio-frequency interference (RFI) in 3-D integrated circuits. It is still challenging to suppress RFI in the practical cavities, where the space is extremely constrained. In this work, the working mechanism and design method of the noise suppression sheet (NSS) is quantitatively studied, serving as an efficient approach to suppress RFI within an electrically small size in these microwave cavities. The analysis is based on the dispersion relationship derivation of the NSS-loaded PPW structure. Both the derived formulas and the numerical study reveal that the imaginary part of the permeability, that is, $\mu _{i}$ , of the NSS plays a key role in increasing the reflection and attenuation loss, and thus obtaining a high RFI suppression level. Further study indicates even when the NSS’s profile is lower than 10% of the cavity’s height and the length is lower than $0.1\lambda _{0}$ , its suppression level up to 10 dB can be well accomplished, which is deemed difficult to achieve by using conventional methods. Moreover, this method is, respectively, applied in three practical engineering scenarios for the RFI suppression, that is, heatsink package above a chip, power distributed network (PDN), and flexible circuit. Good agreement is observed between the measurement results and the simulated ones, which confirmed the efficacy of our quantitatively developed NSS. The proposed method is promising for broad industrial applications, such as tiny chip packages, multi-channel systems, and flexible electronics. [ABSTRACT FROM AUTHOR]

Published

2022

17. Generation and manipulation of phonon lasering in a two-drive cavity magnomechanical system

Author

Xiu-Yu Zhang, Cong Cao, Yong-Pan Gao, Ling Fan, Ru Zhang, and Chuan Wang

Subjects

phonon laser, cavity magnomechanics, two-drive approach, YIG sphere, microwave cavity, Science, Physics, QC1-999

Abstract

A simple and feasible scheme for the generation and manipulation of phonon lasering is proposed and investigated based on a generic three-mode cavity magnomechanical system, in which a magnon mode couples simultaneously with a microwave cavity mode and a phonon mode. In sharp contrast to all previous phonon lasering schemes with only a single drive, the input pump field for the system in the proposed scheme is split into two microwave driving fields to drive the microwave cavity mode and the magnon mode, respectively. The impact of changing relative phase and relative amplitude ratio of the two microwave drives on mechanical gain, stimulated emitted phonon number, threshold power, and phonon emission line shape are theoretically and numerically investigated. The results indicate that the phonon laser action can be effectively controlled simply by adjusting the relative phase and relative amplitude ratio, so additional and tunable degrees of freedom are introduced to control the phonon laser. Considering the experimental feasibility of the generic cavity magnomechanical system and the two-drive approach, the present scheme provides a potentially practical route for the development of tunable phonon lasering devices with low-threshold, high-gain, and narrow-linewidth properties based on the platform of cavity magnomechanics.

Published

2023

18. Cryogenic platform to investigate strong microwave cavity-spin coupling in correlated magnetic materials.

Author

Jones AK, Mourigal M, Mounce AM, and Lilly MP

Abstract

We present a comprehensive exploration of loop-gap resonators for electron spin resonance (ESR) studies, enabling investigations into the hybridization of solid-state magnetic materials with microwave polariton modes. The experimental setup, implemented in a Physical Property Measurement System by Quantum Design, allows for measurements of ESR spectra at temperatures as low as 2 Kelvin. The versatility of continuous wave ESR spectroscopy is demonstrated through experiments on CuSO4⋅5H 2 O and MgCr 2 O 4 , showcasing the g-tensor and magnetic susceptibilities of these materials. The study delves into the challenges of fitting spectra under strong hybridization conditions and underscores the significance of proper calibration and stabilization. The detailed guide provided serves as a valuable resource for laboratories interested in exploring hybrid quantum systems through microwave resonators., (Creative Commons Attribution license.)

Published

2024

19. Characterization of magnetic levitation within a microwave cavity

Author

Raut, Nabin K

Subjects

Physics, Cavity Optomechanics, Magnetic Levitation, Meissner Levitation, Microwave Cavity, Quantum Information Processing, Superconducting Transition

Abstract

Levitating, controlling, and detecting the motion of mesoscopic objects is useful for inertial sensing and fundamental studies in quantum physics. We report the first experimental measurements of Meissner-effect levitation for a sequence of identical millimeter-scale neodymium magnets having varying strengths within a cm-scale superconducting aluminum coaxial quarter-wave stub cavity. We experimentally, theoretically, and analytically characterized Meissner-effect levitation within a 10 GHz superconducting aluminum coaxial quarter-wave stub cavity for a sequence of identically shaped millimeter-scale neodymium magnets having varying strengths (1.22-1.47 T). Magnet levitation within the cavity is accompanied by both gradual and abrupt shifts in the resonance frequency (with a height sensitivity as large as 400 MHz/mm) as well as changes in the total quality factor (8%-17%) as a function of temperature during the superconducting transition of the aluminum cavity. The experimental observation is confirmed with a cylindrical and spherical magnet. The controlled heating and cooling of the cavity show hysteresis in the frequency shift. Furthermore, the experimental observation has shown excellent agreement with finite element simulations, room temperature measurements, and a lumped element model.

Published

2022

20. Kerr-Nonlinearity-Triggered Nonclassicality of Magnons in a Photon-Magnon Coupling System

Author

Xi Jiang, Shiqing Tang, and Songsong Li

Subjects

microwave cavity, photon, magnon, nonclassicality, Applied optics. Photonics, TA1501-1820

Abstract

Hybrid quantum systems have attracted much attention due to the fact that they combine the advantages of different physical subsystems. Cavity QED (cavity quantum electrodynamics) with magnons is a hybrid quantum systems that combines a YIG (Yttrium Iron Garnet) sphere and a 3D (three-dimensional) rectangular microwave cavity. Based on this hybrid photon-magnon system, we obtain an approximate analytic solution by the RWA (rotating wave approximation) with an ingenious transformation. After skillfully diagonalizing the Hamiltonian, we show that the Kerr-nonlinearity interactions could yield a negativity value of the Wigner function, periodic quadrature squeezing effects, antibunching property, and field nonclassicality in the magnon. Our work may stimulate the study of nonclassicality of photon-magnon coupling systems and its potential applications in quantum information processing.

Published

2022

21. Design and Characterization of Au/CdSe/GeO2/C MOSFET Devices

Author

Najla M. Khusayfan, Hazem K. Khanfar, and Seham R. Alharbi

Subjects

CdSe/GeO2, MOSFET, band diagram, microwave cavity, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Abstract Herein, metal-oxide-semiconductor fields effect transistors (MOSFET) are fabricated and characterized. p − type germanium dioxide coated onto Au/ n-CdSe substrates and top contacted with carbon point contacts is used to form the MOSFET devices. The structural investigations which were carried out with the help of X-ray diffraction technique revealed large lattice mismatched polycrystalline layers of CdSe and GeO2. The design of the energy band diagram has shown the formation of two Schottky arms (Au/ n − CdSe, C/GeO2) at the interfaces of the n − CdSe/ p − GeO2 layers. The capacitance-voltage characteristics which are recorded in the frequency domain of 1.0-50.0 MHz revealed the ability of formation of NMOS and PMOS layers. The signal frequency controlled built in potential is tunable in the range of 2.34 and 5.18 eV. In addition, the conductance and capacitance spectral analyses in the frequency domain of 10-1800 MHz revealed the domination of current conduction by tunneling and correlated barriers hoping below and above 760 MHz, respectively. In addition to its features as MOSFET devices, the Au/CdSe/GeO2/C hybrid devices are found to be appropriate for use as microwave cavities.

Published

2021

22. Meissner Levitation of a Millimeter-Size Neodymium Magnet Within a Superconducting Radio Frequency Cavity.

Author

Raut, Nabin K., Miller, Jeffery, Pate, Jacob, Chiao, Raymond, and Sharping, Jay E.

Subjects

*MEISSNER effect, *SUPERCONDUCTING transition temperature, *RADIO frequency, *MAGNETS, *MAGNETIC suspension, *LEVITATION, *PERMANENT magnets

Abstract

We report on the magnetic levitation of a millimeter-sized neodymium permanent magnet within the interior of a superconducting radio frequency (SRF) cavity. To the best of our knowledge, this is the first experimental work on levitating a magnet within an SRF cavity. The cavity is a coaxial quarter-wave microwave resonator made from 6061 aluminum, having a resonance frequency of 10 GHz and a loaded Q of 1400. The cylindrical magnet (N50) has a height of 1 mm, a diameter of 0.75 mm, a mass of 4 mg, and a remanence of 1.44 T. This produces a peak magnetic field 140 times greater than the critical field of aluminum. The magnet is placed either on the top of the coaxial portion of the cavity or on the cavity floor before cooling it below the superconducting transition temperature of aluminum. The coaxial mode's resonance frequency shifts as a function of the levitation height of the magnet and gives an idea of the magnet's position and mechanical motion. We observe a transition at a temperature of 650 mK where the Meissner effect levitates the magnet as the material beneath the magnet becomes superconducting. The magnet is levitated to a height of 2.5 mm above the surface of the cavity stub, which is a sufficient separation for the field strength of the magnet at the surface of the stub to be less than the critical field strength of the superconducting aluminum. We measure a 120 MHz upshift in the cavity resonance as the magnet is levitated from the top of the stub and 15 MHz downshift as it levitates from the floor of the cavity. Our measurements are consistent over several heating and cooling cycles. Our work provides a path towards a novel optomechanical system. [ABSTRACT FROM AUTHOR]

Published

2021

23. Magnon Chaos in $PT$-Symmetric Cavity Magnomechanics

Author

Mei Wang, Duo Zhang, Xiang-Hu Li, Yu-Ying Wu, and Zhao-Yu Sun

Subjects

$PT$ -symmetry, Kerr nonlinearity, magnetostrictive interaction, microwave cavity, magnon chaos, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467

Abstract

Here, we research a novel cavity magnomechanical system, where the magnon mode with Kerr nonlinearity driven by a microwave field couples to a phonon mode with a magneostrictive nonlinear interaction (radiation pressure-like). Based on these nonlinear properties, we numerically demonstrate magnon chaos in the PT-symmetry and PT-symmetry broken regimes in the system. In the PT-symmetry broken phase, the magnon-chaos driving threshold is lowered to a rather low levels benefited from the enhancement of the system nonlinearities. Moreover, by expenediently manipulating the phase transition between PT-symmetry and PT-symmetry broken regimes, we can switch the system between into and out of chaotic regimes. Our work may broaden the cavity magnomehcnaics and provide a promising application for magnetic chaos-related security communications.

Published

2019

24. Yb/InSe/SiO₂/Au Straddling-Type Tunneling Devices Designed As Photosensors, MOS Capacitors, and Gigahertz Bandstop Filters.

Author

Alfhaid, Latifah Hamad Khalid, Qasrawi, A. F., and AlGarni, Sabah E.

Subjects

*TUNNEL design & construction, *PHOTODETECTORS, *ELECTRON tunneling, *ELECTRIC capacity, *CAPACITORS, *CAPACITANCE-voltage characteristics, *THIN films, *METAL oxide semiconductor capacitors

Abstract

In this work, amorphous InSe thin films coated with 30–160-nm-thick SiO2 are used as an active material to fabricate multifunctional devices. The n-InSe/p-SiO2 layers that are deposited onto ytterbium substrates are optically and electrically characterized. It was observed that the coating of SiO2 nanosheets onto the surface of InSe enhances the light absorbability in the near-infrared range without remarkable altering of the bandgap. Significant increase in the steady-state photocurrent values accompanied by faster photocurrent responses resulted from the coating of SiO2 nanosheets. Electrically, while the Yb/InSe/Au channels display tunneling Schottky barrier characteristics, the Yb/InSe/SiO2/Au channels show pn junction features. Both channels displayed metal–oxide–semiconductors (MOS) capacitance–voltage characteristics. In addition, the analyses of the current–voltage characteristics have shown that the currents in the Yb/InSe/Au and Yb/InSe/SiO2(30 nm)/Au channel are dominated by electric field-assisted thermionic emission (tunneling) of charge carriers through barriers of widths of 18/14 and 30/16 nm under reverse-/forward-biasing conditions, respectively. Further increase in the oxide layer thickness lowered the barrier height of the devices. On the other hand, when an ac signal of low amplitude is imposed through the device channels, the conductance, capacitance, and reflection coefficient spectra displayed bandstop filter characteristics near 1.6 GHz. The microwave cutoff frequency spectra show a remarkable increase in the cutoff frequency values as a result of the coating of InSe with SiO2 nanosheets. The features of the device assure its applicability as rectifying diodes, fast photosensors, MOS capacitors, and microwave bandstop filters. [ABSTRACT FROM AUTHOR]

Published

2021

25. Yb/InSe/Sb2Te3/Au BROKEN GAP HETEROJUNCTION DEVICES DESIGNED AS CURRENT RECTIFIERS, TUNABLE MOS CAPACITORS AND GIGAHERTZ MICROWAVE CAVITIES.

Author

ALFHAID, L. H. K., QASRAWI, A. F., and ALGARNI, S. E.

Subjects

*CAVITY resonators, *ELECTRIC capacity, *HETEROJUNCTIONS, *CAPACITANCE-voltage characteristics, *CARRIER density, *CAPACITORS, *YTTERBIUM, *TELLURIUM

Abstract

Herein, we report the design and experimental characterization of a broken gap heterojunction devices fabricated by vacuum evaporation of Yb/InSe/Sb2Te3/Au stacked layers. The structural characterizations of the stacked layers revealed an amorphous/polycrystalline heterojunction type. The measurements of capacitance-voltage characteristics in the frequency domain of 1.0-9.0 MHz displayed tunable metal-oxidesemiconductor (MOS) characteristics. The frequency dependent built-in voltage, depletion width, and free carrier density is also investigated. In addition, the analyses of currentvoltage characteristics have shown that the device displays highly stable current rectification ratios of ~103 above 0.20 V. Moreover, the ac signal analyses in the frequency domain of 10-1800 MHz have shown the possible tunability of the conductance and capacitance over a wide range of frequency. Furthermore, the microwave cutoff frequency spectra indicated increasing cutoff frequency limits with increasing incident signal frequency. The microwave cutoff frequency reached 7.1 GHz for a propagating signal of frequency of 1800 MHz. [ABSTRACT FROM AUTHOR]

Published

2021

26. Electrically detected magnetic resonance in semiconductor and carbon nanodevices

Author

Lang, Volker, Briggs, Andrew, Ardavan, Arzhang, and Morton, John J. L.

Subjects

620.5, Nanomaterials, Defect analysis, Nanostructures, Quantum information processing, Semiconductor devices, Semiconductors, Silicon, Condensed Matter Physics, magnetic resonance, electrically detected magnetic resonance, field-effect transistor, solar cell, silicon, Czochralski silicon, carbon, carbon nanotube, quantum information, microwave cavity, semiconductor

Abstract

Electrically detected magnetic resonance (EDMR) is a sensitive spectroscopic technique, which can be used to readout few to single electron spins in semiconductor and carbon nanodevices for applications in solid state quantum information processing (QIP). Since only electrically active defects contribute to the EDMR signal, this technique can be used further to investigate defects and impurities in photovoltaic devices, in which they limit the sunlight-to-energy conversion efficiency significantly. Here, I employ X-band EDMR for semiconductor defect analysis and identify the most important recombination centres in Czochralski silicon with oxide precipitates, which can be intentionally grown to confine detrimental metallic impurities to inactive regions of the wafer in order to serve as a defect-free substrate for modern silicon photovoltaic devices. Those experiments show that oxide precipitation is accompanied by the formation of silicon dangling bonds. Furthermore, I describe a very promising route towards the fabrication and readout of few to single electron spins in carbon nanotube devices, which can be characterised structurally via transmission electron microscopy in order to relate their electrical and spin properties with their structure. Finally, I employ EDMR to read out electron spin states in donor-doped silicon field-effect transistors as a prerequisite for their application in QIP. I report on a novel cryogenic probe head for EDMR experiments in resonant microwave cavities operating at 0.35 T (9.7 GHz, X-band) and 3.34 T (94 GHz, W-band). This approach overcomes the inherent limitations of conventional X-band EDMR and permits the investigation of paramagnetic states with a higher spectroscopic resolution and signal intensity. Both advantages are demonstrated and discussed. I further report on a novel mechanism giving rise to the EDMR effect in donor-doped silicon field-effect transistors, which is capable of explaining why the EDMR signal intensities of the conduction electrons are enhanced by a factor of ∼100, while the donor resonance signals increase by a factor of ∼20 from X- to W-band only. The spin-relaxation and dephasing times are extracted from a series of pulsed-EDMR measurements and confirm this model. The author gratefully acknowledges funding from Trinity College Oxford, Department of Materials, EPSRC DTA, and Konrad-Adenauer-Stiftung e.V. (Begabtenförderung).

Published

2012

27. Experimental Investigation on the Interaction Mechanism Between Microwave Field and Semiconductor Material

Author

Yong Gao, En Li, Gaofeng Guo, and Hu Zheng

Subjects

Microwave cavity, microwave field, measurement, nonlinear dielectric, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

An experimental method and apparatus for investigating the interaction mechanism between microwave field and semiconductor material are presented in this paper. The investigation is based on a dual-mode compressed rectangular cavity, which includes the TE102 and TE103 modes. The TE102 mode is used for providing the stimulus signal, which supplies the microwave field during the experiment, and the TE103 mode is for testing. The two modes are individually coupled to the cavity, and two band-stop filters are introduced to isolate the signals coming from both the modes. A directional coupler is utilized to monitor the power level of the stimulus signal. Experimental results demonstrate that microwave field may affect the inherent characteristics of indium phosphate, a typical kind of semiconductor materials, which eventually leads to the nonlinear behavior of the dielectric property. After the microwave field strength exceeds a critical value, the nonlinear behavior of the microwave materials becomes more and more drastic along with further increasing field strength, and according to the particular experiment setup, we conclude that the nonlinear behavior is not caused by microwave thermal effect, but some inherent characteristics of the material itself. In addition, the experimental method and apparatus can also be employed to predict the consequences of the non-thermal action of microwave effect of other high-power microwave material under microwave field.

Published

2018

28. Au/As2Se3/Ag/As2Se3/Yb Schottky Barriers Designed as Multifunctional Devices.

Author

Al Harbi, S. R. and Qasrawi, A. F.

Subjects

*SCHOTTKY barrier, *REFLECTANCE, *STANDING waves, *VACUUM, *ELECTRIC capacity, *MOLECULAR clock

Abstract

In this article, Au/As2Se3/Ag/As2Se3/Yb Schottky barriers are formed and characterized. The devices prepared by the thermal evaporation technique under vacuum pressure of 10−5 mbar are observed to exhibit metal-induced crystallization process when coated onto Au substrates. Electrically, the arsenic selenide-based Schottky devices exhibited typical metal-oxide-semiconductor (MOS) characteristics with a built-in potential of 0.17 eV. The device shows resonance–antiresonance switching, negative capacitance (NC) effect, and high to low conductance switching features in the frequency domain of 10–1800 MHz. In addition, measurement of the impedance, amplitude of reflection coefficient, return loss (Lr), and voltage standing wave ratio (VSWR) spectra in the same domain have shown that the Au/As2Se3/Ag/As2Se3/Yb Schottky barriers display band stop features at 1180 MHz. The Lr and VSWR values at this critical frequency are 29.1 dB and 1.1, respectively. The electrical characterizations of the Au/As2Se3/Ag/As2Se3/Yb MOS devices have confirmed their suitability for use as parasitic capacitance cancellers, noise reducers, and as switching clock with selective switching time scales of switching delay time less than 0.40 ns. [ABSTRACT FROM AUTHOR]

Published

2020

29. Characterization of Au/As2Se3/MoO3/Ag hybrid devices designed for dual optoelectronic applications.

Author

Kayed, T.S. and Qasrawi, A.F.

Abstract

In this work, hybrid devices composed of n − As 2 Se 3 / p − MoO 3 encapsulated between two Schottky shoulders (Au/ n -As 2 Se 3 , Ag/MoO 3) are prepared and characterized. While the structural analyses proofed the preferred growth of monoclinic MoO 3 onto amorphous layers of As 2 Se 3 , the spectroscopic ellipsometry analysis revealed the high frequency dielectric constants, the effective mass and the negative pseudodielectric constant values. Electrically, the hybrid device displayed both tunneling and standard diode characteristics. As passive mode devices, the capacitance-voltage characteristics displayed the accumulation-depletion -inversion modes in the device. Furthermore, the conductivity spectral analysis has shown that the current conduction is dominated by the quantum mechanical tunneling and correlated barriers hoping mechanisms. The amplitude of the reflection coefficient and the return loss spectral analyses indicated that the hybrid devices are band stop filters in addition to it is usability as nonlinear optical interfaces, CMOS device and tunneling diodes. Image 1 • Au/n-As 2 Se 3 /p-MoO 3 /Ag hybrid devices are fabricated and characterized. • The structure and morphology of the device is investigated. • The pseudo-dielectric dispersion is studied by spectral ellipsometry technique. • The current and capacitance-voltage characteristics are analyzed. • The impedance spectroscopy in the 10–1800 MHz frequency domain is reported. [ABSTRACT FROM AUTHOR]

Published

2020

30. Microwave Quantum Photonics

Author

Fan, Bixuan, Milburn, Gerard J., Stace, Thomas M., Gisin, Nicolas, Series editor, Laflamme, Raymond, Series editor, Lenhart, Gaby, Series editor, Lidar, Daniel, Series editor, Milburn, Gerard J., Series editor, Ohya, Masanori, Series editor, Rauschenbeutel, Arno, Series editor, Renner, Renato, Series editor, Schlosshauer, Maximilian, Series editor, Weinstein, Yaakov S., Series editor, Wiseman, H. M., Series editor, Hadfield, Robert H., editor, and Johansson, Göran, editor

Published

2016

31. Design, Fabrication, and Characterization of a High-Frequency Microwave Cavity for HAYSTAC

Author

Simanovskaia, Maria

Subjects

Astrophysics, Electromagnetics, axion, dark matter, electromagnetic design, microwave cavity

Abstract

The nature of dark matter is one of the most outstanding mysteries in science today. Possibilities for its composition range from black holes to heavy particles that can be detected by their collisions with atomic nuclei to light particles that act like a coherent field. Sensitive experiments have not yet been able to detect dark matter. A case can be made that the most promising dark matter candidate is the axion, which was invented to solve the strong charge-parity problem in the standard model of particle physics. If the axion exists, it could be produced in abundance and constitute a major component of dark matter.In the presence of a magnetic field, axions will be converted to an oscillating electromagnetic field with a frequency approximately corresponding to the axion mass. We can detect this electromagnetic field as a power excess spectrally coincident with the resonance of a microwave cavity. Each microwave cavity can provide good sensitivity in the search for axions over a limited frequency range, but we must consider new technologies to probe the full axion parameter space in a reasonable amount of time. Both as a testbed for innovative cavity and amplifier concepts and as a data pathfinder for higher frequencies, the Haloscope at Yale Sensitive to Axion Cold dark matter (HAYSTAC) was the first cavity experiment to use a dilution refrigerator and commission a squeezed-state receiver to circumvent the Standard Quantum Limit. The HAYSTAC Phase I and II cavity is a cylinder with an internal rod that rotates off-center and tunes the mode-of-interest resonance frequency between 3.4 and 5.8 GHz in a volume of 1.5 L. Recent theoretical work favors axions between 4 and 12 GHz. I examined various cavity designs to access higher frequencies in this range and determined that a seven-rod cavity design would be optimal with a volume of 1.7 L for a frequency range between approximately 5.5 and 7.5 GHz. I designed this seven-rod cavity, constructed it, and characterized it in detail for use on HAYSTAC. My cavity design allows access to this well-motivated axion mass range with high sensitivity by increasing accessible frequencies without sacrificing performance. This seven-rod concept can be extended to higher frequencies.

Published

2020

32. Quarter-wavelength E‖H Beltrami cavity resonators

Author

10283657, Mochizuki, Ryo, Shinohara, Naoki, Sanada, Atsushi, 10283657, Mochizuki, Ryo, Shinohara, Naoki, and Sanada, Atsushi

Abstract

In this paper, we present the design and implementation methods of quarter-wavelength resonators accommodating Beltrami standing waves with parallel electric and magnetic (E‖H) fields. The resonator is bounded by the quarter-wavelength longitudinal electromagnetic conductor (LEMC), the circumferential electromagnetic conductor (CMEC), and the radial electromagnetic conductor (REMC). The LEMC, CEMC, and REMC boundaries are artificially implemented by the circumferentially aligned corrugation, concentrically aligned circular fins, and axisymmetrically aligned radial fins, respectively. The coupling control methods by introducing slots in the CEMC and REMC with the external TM01 and TE01 circular waveguides are presented. We design the quarter-wavelength resonators with the implemented LEMC, CEMC, and REMC boundaries with controlled external couplings and numerically demonstrate their E‖H properties, which confirms the validity of the proposed design method.

Published

2023

33. Assessing Water-Holding Capacity (WHC) of Meat Using Microwave Spectroscopy

Author

Abdullah, B. M., Cullen, J. D., Korostynska, O., Mason, A., Al-Shamma’a, A. I., Mukhopadhyay, Subhas Chandra, Series editor, Mason, Alex, editor, Jayasundera, Krishanthi Padmarani, editor, and Bhattacharyya, Nabarun, editor

Published

2014

34. Atomic and Molecular Oscillators

Author

Major, F. G. and Major, F. G.

Published

2014

35. FORMATION AND NEGATIVE CAPACITANCE EFFECT IN Au/Bi2O3/ZnS/Ag HETEROJUNCTIONS DESIGNED AS MICROWAVE RESONATORS.

Author

AL GARNI, S. E. and QASRAWI, A. F.

Subjects

*ENERGY bands, *IMPEDANCE spectroscopy, *HETEROJUNCTIONS, *VALENCE bands, *NANOPARTICLES

Abstract

In this article, the physical design, energy band diagram, temperature dependent electrical resistivity and the impedance spectroscopy measurements of the Au/Bi2O3/ZnS/Ag isotype heterojunction devices are reported. The devices are prepared by the thermal evaporation technique under vacuum pressure of 10-5 mbar. Structural, compositional and morphological studies has shown the presence of an expansion in the lattice of Bi2O3 associated with increased strain and dislocation density and decreased grain size as a result of ZnS interfacing. The design of the band diagram indicated that the formed heterojunction exhibit large valence and conduction band offsets that forces charge accumulation at the interface. The Au/Bi2O3/ZnS/Ag device displays negative capacitance (NC) effect in the frequency domain of 0.01-1.50 GHz. The NC effect is interrupted by a resonance-antiresonance phenomenon in the frequency domain of 0.90-1.07 GHz. In addition to the NC effects, the device under study exhibited reflection coefficient and return loss spectra that nominate it for use as microwave cavities or as low pass band filters. [ABSTRACT FROM AUTHOR]

Published

2018

36. Analysis of defect chemistry and microstructural effects of non-stoichiometric ceria by the high-temperature microwave cavity perturbation method

Author

Gunter Hagen, Holger Fritze, Ralf Moos, Iurii Kogut, and Carsten Steiner

Subjects

Materials science, Chemical engineering, Materials Chemistry, Ceramics and Composites, Dielectric, Partial pressure, Microstructure, Polarization (electrochemistry), Stoichiometry, Grain size, Microwave, Microwave cavity

Abstract

The defect chemistry of ceria has been studied using a microwave resonator. The dielectric properties of powder samples were investigated up to 600 °C and at different oxygen partial pressures pO2 (10-26 – 0.2 bar) and evaluated using the microwave cavity perturbation theory. For the ceria powder, an activation of the oxygen incorporation and release kinetics was observed from 480 °C onwards. The data suggest that the increased losses in non-stoichiometric ceria originate from the small polaron hopping mechanism, as known from literature. In addition, an increase in material polarization due to the formation of oxygen vacancies was experimentally observed. A comparison with sintered, coarse-grained samples of the same material and with literature data also demonstrated the importance of the microstructure for the defect chemistry of ceria. For the powder (ca. 80 nm grain size), significantly higher electronic conductivities (assumedly due to the higher concentration of small polarons) and lower activation energies were detected at 600 °C. On the other hand, lower conductivities, controlled by the concentration of acceptor cations in the material were reported for the sintered samples (1.1 µm) at this temperature. The findings are well in-line with existing defect chemical models of ceria. This study presents an analysis of the microwave behavior of ceria and provides insights into intrinsic and extrinsic mechanisms of oxygen exchange in ceria. The findings also contribute to a better understanding of microwave-based state diagnosis of three-way catalysts in automotive applications.

Published

2022

37. Challenges in the microwave heating of lunar regolith – Analysis through the design of a microwave heating Demonstrator (MHD) payload

Author

Andrew Morse, James Bowen, Alberto Garbayo, Sam Reeve, Thomas Le Toux, Sungwoo Lim, Eneko Lekuona, and Mahesh Anand

Subjects

Atmospheric Science, business.industry, Payload, Astrophysics::Instrumentation and Methods for Astrophysics, Aerospace Engineering, 3D printing, Astronomy and Astrophysics, Context (language use), In situ resource utilization, Regolith, Geophysics, Space and Planetary Science, Microwave heating, Physics::Space Physics, General Earth and Planetary Sciences, Environmental science, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, Magnetohydrodynamics, business, Microwave cavity

Abstract

Sustainable exploration of the Moon could benefit from a microwave heating-based 3D Printing technology for In-Situ Resource Utilisation (ISRU) purposes such as for the fabrication of habitats and extraction of resources on the Moon. In this context, we have developed a Microwave Heating Demonstrator (MHD) payload concept, which can perform pre-defined ISRU experiments on the lunar surface. The MHD payload would also produce scientifically valuable data in its own right, which would help to establish fundamental criteria for developing a microwave heating-based 3D Printing technique, ultimately enabling lunar construction and other ISRU-derived mission activities.\ud \ud One of the major design criteria of the MHD payload was to enable sustainable heating performance at low microwave power, e.g., 250 W. This paper discusses some non-negligible phenomena during the microwave heating of lunar regolith, which need to be considered for future mission applications. We also present a design of the MHD payload development, focusing on the heating performance of the microwave cavity.

Published

2022

38. Enerji sönümleme uygulamalarında optomekanik aygıtların kullanımı

Author

Lee, ChulHyeong and Hanay, Mehmet Selim

Subjects

NEMS, Microwave cavity, Racetrack resonators, Ring resonators, Optomechanics

Abstract

Cataloged from PDF version of article. Thesis (Master's): Bilkent University, Graduate Program in Materials Science and Nanotechnology, İhsan Doğramacı Bilkent University, 2023. Includes bibliographical references (leaves 52-56). Resonance energy dissipation mechanism has been gaining importance in the interest of sensing applications. As such, the capacity for precise and fast measurement of the transient phase of motion has been desirable. The development of optomechanics in recent years has enabled such a fast scheme. Here a design, setup, and measurement of a silicon nitride optomechanical system is explored. Fundamental parameters of the design are investigated with simulation analysis. Grating structures, waveguides, and resonator parameters are explored. A series of optical resonance responses are observed, and the resonance characteristics are analyzed for optomechanical devices of combinations of design parameters. Measurements on devices of different nanomechanical beam modulation schemes are performed. To translate the technique from the optical to microwave domain, an integration of a split ring resonator (SRR) cavity and NEMS device is explored. Mode simulation of the modified cavity design is done. A technique of alignment of EBL to an existing pattern on an insulating surface is optimized. The studied designs leave possibilities for applications in real-time mass sensing and fundamental studies on energy dissipation mechanisms. by ChulHyeong Lee M.S.

Published

2023

39. Intelligent Tuning of Microwave Cavity Filters Using Granular Multi-Swarm Particle Swarm Optimization

Author

Weihua Cao, Bi Leyu, Wenkai Hu, and Min Wu

Subjects

Automatic tuning, Series (mathematics), Control and Systems Engineering, Computer science, Musical tuning, Process (computing), Electronic engineering, Particle swarm optimization, Swarm behaviour, Function (mathematics), Electrical and Electronic Engineering, Microwave cavity

Abstract

The tuning of microwave cavity filters (MCFs) is a complex process to improve the filtering performance. In practice, the tuning is mostly conducted in a manual way, and thus is time and resource intensive. Toward the demand for automatic tuning of MCFs with high accuracy and efficiency, this article proposes an intelligent tuning method for MCFs via modeling and optimization. The main contributions are threefold as follows: 1) A series of performance evaluation functions are defined to comprehensively characterize the tuning output; 2) a block modeling method is proposed to construct the electromechanical characteristic model to facilitate the calculation of the cost function; 3) an improved particle swarm optimization (PSO) algorithm, named granular multi-swarm PSO (GMS-PSO), is proposed to achieve quick search of optimal combinations of the tunable components. The effectiveness and practicality of the proposed method are demonstrated by experiments with a real intelligent tuning system.

Published

2021

40. Are Scattering Properties of Networks Uniquely Connected to Their Shapes?

Author

Hul, Oleh, Ławniczak, Michał, Bauch, Szymon, Sawicki, Adam, Kuś, Marek, Sirko, Leszek, Egger, Reinhold, editor, Matrasulov, Davron, editor, and Rakhimov, Khamdam, editor

Published

2013

41. Design of a Miniaturized Cavity for Space Hydrogen Masers

Author

Yang, R. F., Zhou, T. Z., Gao, L. S., Sun, Jiadong, editor, Liu, Jingnan, editor, Yang, Yuanxi, editor, and Fan, Shiwei, editor

Published

2012

42. Hydraulic pressure and temperature effects on the structural, morphological and electrical properties of SeO2 powders

Author

Algarni, Sabah E., Qasrawi, A. F., and Khusayfan, Najla M.

Published

2022

43. Development of hotspot mapping technique in microwave cavity using resistive sheet

Author

Irineu Petri Júnior, Felipe Leonardo Bacelos, André Silveira Felipe, and Felipe Orlando da Costa

Subjects

Electromagnetic field, Resistive touchscreen, Materials science, Multi-mode optical fiber, General Chemical Engineering, Acoustics, Hotspot (geology), Homogeneity (physics), Electromagnetic radiation, Microwave, Microwave cavity

Abstract

Microwave ovens function through the emission of electromagnetic waves, which reflect off the walls of the cavities causing local fluctuations to the electromagnetic field. In multimode cavities, multiple hotspots are generated due to the presence of various nodes, causing the localized overheat. Understanding the location of the hotspots is important to improve the heating efficiency and homogeneity of the microwave. This work aimed to propose an innovative technique for mapping the hotspots inside the multimode cavities microwave, using a resistive sheet made of polypropylene and activated carbon in contents of 5, 10 and 20%. To validate the experimental mapping technique, numerical simulations were used to predict the electromagnetic fields inside the cavity, and the simulations were then compared to the experimental result. The numeric models were validated through the experimentally determined output power. The experimental mapping results showed it was possible to reproduce clear and easy identifiable hotspots in different heights inside cavities using resistive sheets with activated carbon contents of 10 and 20%. The numerical simulations showed results for the output power that were statistically equal to the experimental results, validating its application for the prediction of the electromagnetic and thermo fields. Comparing the experimental and numerical mapping of the hotspots, a consistent match was verified between the generated profiles. Thus, the developed mapping technique managed to predict adequately the hotspots inside microwave cavities, which is useful for applications such as scale-ups and the optimization of industrial cavities.

Published

2021

44. Eigenmode computation of cavities with perturbed geometry using matrix perturbation methods applied on generalized eigenvalue problems.

Author

Gorgizadeh, Shahnam, Flisgen, Thomas, and van Rienen, Ursula

Subjects

*PERTURBATION theory, *GEOMETRY, *MATRICES (Mathematics), *GENERALIZATION, *EIGENVALUES

Abstract

Generalized eigenvalue problems are standard problems in computational sciences. They may arise in electromagnetic fields from the discretization of the Helmholtz equation by for example the finite element method (FEM). Geometrical perturbations of the structure under concern lead to a new generalized eigenvalue problems with different system matrices. Geometrical perturbations may arise by manufacturing tolerances, harsh operating conditions or during shape optimization. Directly solving the eigenvalue problem for each perturbation is computationally costly. The perturbed eigenpairs can be approximated using eigenpair derivatives. Two common approaches for the calculation of eigenpair derivatives, namely modal superposition method and direct algebraic methods, are discussed in this paper. Based on the direct algebraic methods an iterative algorithm is developed for efficiently calculating the eigenvalues and eigenvectors of the perturbed geometry from the eigenvalues and eigenvectors of the unperturbed geometry. [ABSTRACT FROM AUTHOR]

Published

2018

45. Split ring resonator with optimised sensitivity for microfluidic sensing.

Author

Hamzah, Hayder, Lees, Jonathan, and Porch, Adrian

Subjects

*MICROFLUIDIC devices, *MICROWAVE devices, *RESONATORS, *VOLTAGE control

Abstract

In this paper we describe a microwave sensor for microfluidic sensing using a split ring resonator (SRR) with the sample parallel to the electric field to improve its sensitivity. It is designed to operate at 2.5 GHz with a 3 mm active gap region, over a volume of approximately 10 m m 3 . The SRR has been tested with microliter volumes of several common solvents, namely, water, methanol, ethanol, and chloroform, with excellent agreement between simulated and experimental results. Furthermore, two types of common acid and alkaline (HCl and NaOH) have been tested at different pH levels. The sensor showed very good sensitivity for pH change and all the results were found to be statistically significant between the pH groups. The SRR was also shown to be highly sensitive to small changes in salt (NaCl) concentrations. Compared to traditional techniques, this miniaturised SRR method is compatible with lab-on-chip approaches. [ABSTRACT FROM AUTHOR]

Published

2018

46. Concept of multiple-cell cavity for axion dark matter search.

Author

Jeong, Junu, Youn, SungWoo, Ahn, Saebyeok, Kim, Jihn E., and Semertzidis, Yannis K.

Subjects

*AXIONS, *DARK matter, *ASTROPHYSICS, *PARTICLE physics, *NUCLEAR physics

Abstract

In cavity-based axion dark matter search experiments exploring high mass regions, multiple-cavity design is under consideration as a method to increase the detection volume within a given magnet bore. We introduce a new idea, referred to as a multiple-cell cavity, which provides various benefits including a larger detection volume, simpler experimental setup, and easier phase-matching mechanism. We present the characteristics of this concept and demonstrate the experimental feasibility with an example of a double-cell cavity. [ABSTRACT FROM AUTHOR]

Published

2018

47. Atomic Clocks

Author

Wynands, Robert, Muga, Gonzalo, editor, Ruschhaupt, Andreas, editor, and del Campo, Adolfo, editor

Published

2009

48. Quantum Eraser

Author

Hiley, Basil J., Greenberger, Daniel, editor, Hentschel, Klaus, editor, and Weinert, Friedel, editor

Published

2009

49. Smart Electromagnetic Thermites: GO/rGO Nanoscale Thermite Composites with Thermally Switchable Microwave Ignitability

Author

Murtaza Zohair, Olivia L. Smithhisler, Cary L. Pint, Stuart J. Barkley, Adam R. Lawrence, Travis R. Sippel, and James B. Michael

Subjects

Materials science, Graphene, Composite number, Oxide, Thermite, engineering.material, law.invention, Ignition system, chemistry.chemical_compound, Coating, chemistry, law, engineering, General Materials Science, Composite material, Microwave, Microwave cavity

Abstract

This effort demonstrates the development of a novel, graphene oxide nanoscale thermite composite with thermally tunable microwave ignitability. A model thermite system containing nanoscale aluminum and nanoscale iron(II) oxide in a stoichiometric ratio (30/70 wt %) was combined with sheets of graphene oxide (GO) or reduced graphene oxide (rGO) using an immiscible two-fluid sonication and tape casting process. The samples were microwave irradiated within a single-mode resonant microwave cavity to determine the microwave ignition delay. Neat thermites were found to ignite after 4.34 s of microwave illumination, whereas 30 wt % rGO thermite composite ignition delay was an order of magnitude shorter (0.43 s). For most samples (4 of 6 trials), it was found that application of a 30 wt % GO coating inhibits microwave ignition of the thermite. Thermal treatment of the GO thermite composite led to switching of thermites from unignitable to ignitable with microwave field application as short as 0.24 s due to GO reduction. Optimum heat treatment time and GO content are explored with SEM, DSC/TGA-MS, Raman, and XPS deconvolution. This effort demonstrates the use of GO and rGO addition to achieve thermally switchable microwave ignitability to electromagnetically shield or enhance nanoscale energetic ignition by microwave energy.

Published

2021

50. High Flow-Rate Benchtop NMR Spectroscopy Enabled by Continuous Overhauser DNP

Author

Hans Hasse, Raphael Kircher, and Kerstin Münnemann

Subjects

Magnetic Resonance Spectroscopy, Spectrometer, Spins, Chemistry, 010401 analytical chemistry, Spin–lattice relaxation, Analytical chemistry, Water, Electrons, Nuclear magnetic resonance spectroscopy, 010402 general chemistry, Magnetic Resonance Imaging, 01 natural sciences, 0104 chemical sciences, Analytical Chemistry, Volumetric flow rate, Magnet, Microwaves, Polarization (electrochemistry), Microwave cavity

Abstract

Analysis of a fast-flowing liquid with NMR spectroscopy is challenging because short residence times in the magnetic field of the spectrometer result in inefficient polarization buildup and thus poor signal intensity. This is particularly problematic for benchtop NMR spectrometers because of their compact design. Therefore, in the present work, different methods to counteract this prepolarization problem in benchtop NMR spectroscopy were studied experimentally. The tests were carried out with an equimolar acetonitrile + water mixture flowing through a capillary with a 0.25 mm inner diameter at flow rates up to 2.00 mL min–1, corresponding to mean velocities of up to 0.7 m s–1. Established approaches gave only poor results at high flow rates, namely, using a prepolarization magnet, using a loopy flow cell, and using a T1 relaxation agent. To overcome this, signal enhancement by Overhauser dynamic nuclear polarization (ODNP) was used, which is based on polarization transfer from unpaired electron spins to nuclear spins and happens on very short time scales, resulting in high signal enhancements, also in fast-flowing liquids. A corresponding setup was developed and used for the studies: the line leading to the 1 T benchtop NMR spectrometer first passes through a fixed bed with a radical matrix placed in a Halbach magnet equipped with a microwave cavity to facilitate the spin transfer. With this ODNP setup, excellent results were obtained even for the highest studied flow rates. This shows that ODNP is an enabler for fast-flow benchtop NMR spectroscopy.

Published

2021