Your search keyword '"Superconducting"' showing total 1,677 results

1. Electro-Thermal Simulation and Evaluation of Transition Edge Sensor X-ray Microcalorimeter with Mushroom-Type Absorber.

Author

Ota, Ryo, Tanaka, Keita, Hayashi, Tasuku, Miyagawa, Rikuta, Yagi, Yuta, Yamasaki, Noriko Y., and Mitsuda, Kazushisa

Subjects

*ELECTRIC conductivity, *ELECTRIC circuits, *ENERGY dissipation, *SPECTRAL imaging, *X-ray microscopy

Abstract

High-efficiency microcalorimeter arrays are required as imaging spectroscopy for X-ray microscopy in general and for astrophysics. We have developed in-house an array of Transition Edge Sensor (TES) X-ray microcalorimeters with mushroom-type absorbers which have a large area of 260 μ m square with multiple support stems. Insufficient thermal conductivity may degrade the energy resolution. We construct a 3D FEM simulation with thermal conduction and electric feedback circuit of TES. Estimated physical parameters were incorporated into the simulation to reproduce the measured pulse waveforms. As a result, the effect of the large absorber on the degradation of energy resolution was small for the mushroom-type absorber TES calorimeter. [ABSTRACT FROM AUTHOR]

Published

2024

2. New accelerator designs: NIMMS.

Author

Vretenar, Maurizio and Benedetto, Elena

Abstract

Purpose: This article summarises the presentation given at the "Hadrontherapy: status and perspectives" event. Methods: Structure, methodology, and objectives of the Next Ion Medical Machine Study collaboration are introduced. Its four Work Packages are: small synchrotrons for particle therapy, curved superconducting magnets for synchrotrons and gantries, superconducting gantry design, and high-frequency ion linacs. Synchrotrons under study include a superconducting design for carbon ion therapy, and a normal-conducting design for ions up to helium. Superconducting magnet R&D is carried out in two European projects. Within the scope of these projects, five magnet demonstrators with different technologies are in different phases of design and production. Beam optics and mechanical design of a superconducting gantry for carbon ions is being developed. A high-frequency linac design has been completed, and tests are starting on a prototype high-frequency injector. Results: The designs of two facilities based on NIMMS technological developments are presented. A carbon ion research and therapy facility was designed for the SEEIIST project, based on a conventional synchrotron with high beam intensity. A smaller facility aimed at cancer therapy and research with light ions, in particular helium beams has also been designed. Both facilities can produce FLASH-type beams. Conclusions: The traditional design of carbon ion therapy facilities can be improved by adding new features as higher beam intensity and new beam extraction schemes. A cost-effective alternative to the traditional design is a compact facility for light ions, exploiting the potential for treatment with helium ions and allowing an experimental programme with different ion species. [ABSTRACT FROM AUTHOR]

Published

2024

3. The specific heat of superconducting metallic grains in magnetic field.

Author

Yao, Yong, Liu, Yu-Xiao, Luo, Qiang, Tang, Bin, Qu, Hao, and Ma, Lihua

Subjects

*THERMODYNAMICS, *MAGNETIC fields, *HEAT capacity, *SPECIFIC heat, *SPIN-orbit interactions, *ELECTRON spin

Abstract

More and more studies indicate that the effects of quantum size and energy level statistics play a crucial role in the thermodynamic properties of ultrasmall metallic grains. This paper aims to investigate how they affect the specific heat of ultrasmall metallic grains in magnetic field. As the particle size decreases, fluctuation effects and the impact of energy level separation are becoming more and more important. The method of static path approximation (SPA) is adopted to handle the fluctuation effect. Random matrix theory (RMT) is adopted due to its successful description of the energy level of metal nanoparticles. The normalized specific heat of several typical temperatures and electron spins were taken in the calculation, and the results were analyzed. It was found that spin and the spin-orbit coupling affect the specific heat very obviously, and the suppressed high spin weakens the contribution of electrons to the heat capacity. [ABSTRACT FROM AUTHOR]

Published

2024

4. DNA‐Based Conductors: From Materials Design to Ultra‐Scaled Electronics.

Author

Wang, Kexin, Deng, Pu, Lin, Huili, Sun, Wei, and Shen, Jie

Subjects

*QUANTUM tunneling, *QUANTUM electronics, *DNA structure, *DNA nanotechnology, *ELECTROLYTE solutions

Abstract

Photolithography has been the foundational fabrication paradigm in current high‐performance electronics. However, due to the limitation in fabrication resolution, scaling beyond a 20‐nm critical dimension for metal conductors presents a significant challenge for photolithography. Structural DNA nanotechnology emerges as a promising alternative to photolithography, allowing for the site‐specific assembly of nano‐materials at single‐molecule resolution. Substantial progresses have been achieved in the ultra‐scaled DNA‐based conductors, exhibiting novel transport characteristics and small critical dimensions. This review highlights the structure‐transport property relationship for various DNA‐based conductors and their potential applications in quantum /semiconductor electronics, going beyond the conventional scope focusing mainly on the shape diversity of DNA‐templated metals. Different material synthesis methods and their morphological impacts on the conductivities are discussed in detail, with particular emphasis on the conducting mechanisms, such as insulating, metallic conducting, quantum tunneling, and superconducting. Furthermore, the ionic gating effect of self‐assembled DNA structures in electrolyte solutions is examined. This review also suggests potential solutions to address current challenges in DNA‐based conductors, encouraging multi‐disciplinary collaborations for the future development of this exciting area. [ABSTRACT FROM AUTHOR]

Published

2024

5. Superconducting Quantum Computing

Author

Easttom, Chuck and Easttom, Chuck

Published

2024

6. A novel application concept of high-temperature superconducting cable for seabed coils in ship magnetic deperming

Author

Hirota, Megumi

Published

2024

7. Nonequilibrium control of kagome metals

Author

Grandi, Francesco, Thomale, Ronny, and Kennes, Dante M.

Published

2024

8. Application and analysis of superconducting magnetic eddy current heater used in wind thermal power generation system

Author

Wenfeng Zhang, Chen Chen, Zeyuan Liu, Youhua Wang, and Chengcheng Liu

Subjects

heater, magnetic eddy current, superconducting, wind power, Applications of electric power, TK4001-4102

Abstract

Abstract In order to cope with the grid fluctuation caused by large‐scale wind power connected to the grid, the wind thermal power generation system has been proposed and extensively studied. The wind thermal power generation system uses a wind turbine to drive a heat generation device to heat the heat storage medium, which is further exchanged to drive a turbine to generate electricity. A superconducting magnetic eddy current heater (SMH) is proposed for the characteristics of wind thermal power generation system, which uses non‐resistive, large current‐carrying superconducting coils for excitation, and has high output efficiency and power density. The working principle of magnetic eddy current heating is analysed, and the structure of SMH with no ferromagnetic material and two heating screens inside and outside is proposed according to the characteristics of SMH. An analytical model of the SMH is established, and the influence of the structure and materials of the SMH on the magnetic field distribution is analysed. Based on this, a 22‐pole SMH was designed and analysed for output power at 10–20 rpm. A three‐dimensional magnetism‐stress combined analysis model of SMH is established, and the strain and stress characteristics of SMH are simulated under the condition of maximum output power, which verifies the feasibility of the mechanical properties of existing superconducting materials for application in SMH.

Published

2024

9. Application and analysis of superconducting magnetic eddy current heater used in wind thermal power generation system.

Author

Zhang, Wenfeng, Chen, Chen, Liu, Zeyuan, Wang, Youhua, and Liu, Chengcheng

Subjects

*WIND power, *HEAT storage devices, *SUPERCONDUCTORS, *SUPERCONDUCTING coils, *HEATING, *WIND forecasting

Abstract

In order to cope with the grid fluctuation caused by large‐scale wind power connected to the grid, the wind thermal power generation system has been proposed and extensively studied. The wind thermal power generation system uses a wind turbine to drive a heat generation device to heat the heat storage medium, which is further exchanged to drive a turbine to generate electricity. A superconducting magnetic eddy current heater (SMH) is proposed for the characteristics of wind thermal power generation system, which uses non‐resistive, large current‐carrying superconducting coils for excitation, and has high output efficiency and power density. The working principle of magnetic eddy current heating is analysed, and the structure of SMH with no ferromagnetic material and two heating screens inside and outside is proposed according to the characteristics of SMH. An analytical model of the SMH is established, and the influence of the structure and materials of the SMH on the magnetic field distribution is analysed. Based on this, a 22‐pole SMH was designed and analysed for output power at 10–20 rpm. A three‐dimensional magnetism‐stress combined analysis model of SMH is established, and the strain and stress characteristics of SMH are simulated under the condition of maximum output power, which verifies the feasibility of the mechanical properties of existing superconducting materials for application in SMH. [ABSTRACT FROM AUTHOR]

Published

2024

10. 基于Python的超导量子干涉器件仿真优化方法.

Author

秦肖雅, 张樱子, and 张一洲

Abstract

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

Published

2024

11. Manufacturing of the Stainless-Steel Sheathed Magnesium Diboride Superconductor Wire.

Author

Yudanto, Sigit Dwi, Affandi, Ahmad Sigit, and Manaf, Azwar

Subjects

SUPERCONDUCTING wire, COLD rolling, MAGNESIUM diboride, CRITICAL temperature, MAGNESIUM oxide

Abstract

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

Published

2024

12. Resistance at 77 K of two Bi-2223 coils with superconducting joints prepared by incongruent melting.

Author

Kanazawa, Shintetsu and Sekine, Chihiro

Subjects

*SUPERCONDUCTING coils, *CRITICAL currents, *NUCLEAR magnetic resonance, *SUPERCONDUCTING magnets, *MAGNETIC resonance imaging, *ADHESIVE tape, *MELTING

Abstract

A superconducting joint for multi-filamentary Bi2Sr2Ca2Cu3O10+ δ (Bi2223) tape, which has applications in nuclear magnetic resonance and magnetic resonance imaging, has been developed based on incongruent melting and multi-junction methods. In this study, the critical current limit, optimal oxygen annealing conditions, and reproducibility of this joint are experimentally evaluated. The results indicate that the critical current limit of the joint at 77 K is determined by that of the tape. The critical current limit was estimated to be about 40 A. Additional oxygen annealing after heat treatment below 1143 K. appears to have no effect on the critical current, and that above 1153 K slightly increases the critical current. It is found that the multi-junction method effectively increases the reproducibility of obtaining a high critical current. To obtain a high critical current at 77 K, the highest temperature in the joint creation process should be lowered to near the incongruent melting temperature of Bi2223 (about 1133 K in air). Two Bi2223 coils, each with one joint (four junctions), were prepared and their persistent current at 77 K was tested. A persistent current of above 20 A was measured with a resistance of about 10 pΩ. [ABSTRACT FROM AUTHOR]

Published

2024

13. Study of Coupling in Superconducting Transmission Lines.

Author

Valenzuela, D.

Subjects

*ELECTRIC lines, *MICROSTRIP transmission lines, *PASSIVE components, *FREQUENCY spectra, *COPLANAR waveguides, *SURFACE impedance

Abstract

The use of transmission lines is widely accepted in the design of multiple active and passive devices given their capabilities to operate with signals in the whole frequency spectrum. However, a factor that difficult their design is the coupling effect when there are multiple transmission lines in parallel. Depending of the application, this factor could have a beneficial or detrimental effect in transmission lines. In particular, superconducting parametric amplifiers experiment this effect. The focus of this paper to understand the crosstalk so future superconducting parametric amplifiers can be designed considering the crosstalk. The study was achieved using coplanar waveguide transmission lines, artificial coplanar waveguide transmission lines, and microstrip lines. Dimensions of state-of-the-art (SOTA) parametric amplifiers have been used to have a suitable comparison with the nowadays state of the art superconducting parametric amplifiers. [ABSTRACT FROM AUTHOR]

Published

2024

14. Preparation and Peculiar Magnetic Properties at Low Temperatures of La 1.85 Sr 0.15 CuO 4 Nanofibers.

Author

Gao, Shi-Long, Zhang, Ting-Ting, Qiu, Li-Peng, Zhang, Yu-Rui, Cheng, Guo-Ting, Liu, Qi, Han, Wen-Peng, Ramakrishna, Seeram, and Long, Yun-Ze

Subjects

*MAGNETIC properties, *SUPERCONDUCTING transition temperature, *LOW temperatures, *SUPERCONDUCTORS, *PARTICLE size distribution, *NANOFIBERS

Abstract

Herein, the preparation process, morphology, structure, and magnetic properties of La1.85Sr0.15CuO4 (LSCO) cobweb-like nanofibers are reported. LSCO nanofibers with a regular grain size distribution are successfully prepared via electrospinning, followed by calcination. We conducted morphology analysis and elemental distribution using electron microscopy and energy-dispersive X-ray spectroscopy (EDS), respectively. Additionally, magnetic property testing was performed using a vibrating sample magnetometer (VSM) to confirm the superconducting properties of the samples. Interestingly, our samples exhibited a superconducting transition temperature, Tc, of 25.21 K, which showed some disparity compared to similar works. Furthermore, we observed a ferromagnetic response at low temperatures in the superconducting nanofibers. We attribute these phenomena to the effects generated by surface states of nanoscale superconducting materials. [ABSTRACT FROM AUTHOR]

Published

2024

15. Towards 20 T Hybrid Accelerator Dipole Magnets

Author

Ferracin, P, Ambrosio, G, Arbelaez, D, Brouwer, L, Barzi, E, Cooley, L, Fajardo, L Garcia, Gupta, R, Juchno, M, Kashikhin, V, Marinozzi, V, Novitski, I, Rochepault, E, Stern, J, Zlobin, A, and Zucchi, N

Subjects

Engineering, Electrical Engineering, Physical Sciences, Dipole magnets, hybrid magnets, HTS, Nb3Sn magnets, superconducting, Condensed Matter Physics, Electrical and Electronic Engineering, Materials Engineering, General Physics, Electrical engineering, Condensed matter physics

Abstract

The most effective way to achieve very high collision energies in a circular particle accelerator is to maximize the field strength of the main bending dipoles. In dipole magnets using Nb-Ti superconductor the practical field limit is considered to be 8-9 T. When Nb3Sn superconductor material is utilized, a field level of 15-16 T can be achieved. To further push the magnetic field beyond the Nb3Sn limits, High Temperature Superconductors (HTS) need to be considered in the magnet design. The most promising HTS materials for particle accelerator magnets are Bi2212 and REBCO. However, their outstanding performance comes with a significantly higher cost. Therefore, an economically viable option towards 20 T dipole magnets could consist in an 'hybrid' solution, where both HTS and Nb3Sn materials are used. We discuss in this paper preliminary conceptual designs of various 20 T hybrid magnet concepts. After the definition of the overall design criteria, the coil dimensions and parameters are investigated with finite element models based on simple sector coils. Preliminary 2D cross-section computation results are then presented and three main layouts compared: cos-theta, block, and common-coil. Both traditional designs and more advanced stress-management options are considered.

Published

2022

16. Improved Thermal Conductivity at Low Temperatures in Epoxy Nanocomposites by Hexagonal Boron Nitride Aerogels

Author

Miao, Zhicong, Zhao, Yalin, Zhou, Zhengrong, su, Haojian, Jiang, Mingyue, Zhao, Wanyin, Huang, Rongjin, Li, Laifeng, Qiu, Limin, editor, Wang, Kai, editor, and Ma, Yanwei, editor

Published

2023

17. Analysis of the Shielding Effectiveness of Cryogenic Magnetic Shields Used for Testing Superconducting Single-Flux-Quantum Circuit Chips

Author

Wei, Lingjiao, Wang, Guopeng, Li, Jianguo, Ma, Yuexue, Hong, Guotong, Qiu, Limin, editor, Wang, Kai, editor, and Ma, Yanwei, editor

Published

2023

18. A Short Review: Reliability Issues of Lead-Free Sn-Based Alloys for Superconducting Applications

Author

Tan, Y. P., Somidin, F., Mohd Salleh, Mohd Arif Anuar, editor, Che Halin, Dewi Suriyani, editor, Abdul Razak, Kamrosni, editor, and Ramli, Mohd Izrul Izwan, editor

Published

2023

19. Superconducting Saturable Core Reactor as Variable Inductance for Controlling the Power Flow in a Transmission Line

Author

Miúdo, Leonardo, Pina, João Murta, Amaro, Nuno, Rannenberg, Kai, Editor-in-Chief, Soares Barbosa, Luís, Editorial Board Member, Goedicke, Michael, Editorial Board Member, Tatnall, Arthur, Editorial Board Member, Neuhold, Erich J., Editorial Board Member, Stiller, Burkhard, Editorial Board Member, Stettner, Lukasz, Editorial Board Member, Pries-Heje, Jan, Editorial Board Member, Kreps, David, Editorial Board Member, Rettberg, Achim, Editorial Board Member, Furnell, Steven, Editorial Board Member, Mercier-Laurent, Eunika, Editorial Board Member, Winckler, Marco, Editorial Board Member, Malaka, Rainer, Editorial Board Member, Camarinha-Matos, Luis M., editor, and Ferrada, Filipa, editor

Published

2023

20. DC Fault Current Limiters and Their Applications

Author

Li, Bin, Kizilyalli, Isik C., editor, Shen, Z. John, editor, and Cunningham, Daniel W., editor

Published

2023

21. Literature Review of Suspension Systems for Superconducting Elements.

Author

Piacentini, Luca, Dassa, Luca, Perini, Diego, Ratkus, Andris, Torims, Toms, and Uberti, Stefano

Subjects

LITERATURE reviews, MOTOR vehicle springs & suspension, DATABASES, HEATING load

Abstract

When designing suspension systems for superconducting elements, the primary challenge is to strike a balance between limiting the heat load to the cold mass and ensuring the proper mechanical resistance and/or stiffness of the system. This trade-off often leads engineers to choose from a limited set of materials and supporting architectures. The aim of this study is to provide an overview of the different overall designs. Scientific articles were searched within the Google Scholar database using advanced search operators to combine a defined set of keywords. Among the architectures found, the "multi-post" solution and the "8-support" solution are the two most commonly chosen classes. Additionally, a recurrent pattern for the supporting system of superconducting cavities has been identified. The choice of architecture can be correlated with the characteristics of the superconducting element being supported, such as its mass, length, and stiffness. Furthermore, the review provides a conceptual analysis of the possibility of extending these designs to the unconventional environment of rotating machines. [ABSTRACT FROM AUTHOR]

Published

2023

22. Superconductivity in AuGeNi Ohmic contacts to a GaAs-based high mobility two-dimensional electron gas

Author

Beauchamp, Christopher Brian

Subjects

AuGeNi, ohmic contact, superconducting, 2DEG, Transistor, low temperature, nano-electronics, Electronic, GaAs, AlGaAs, semiconductors, heterostructures

Abstract

The initial aim of this thesis was to cool two-dimensional electrons down to temperatures below 10 mK. In order to cool a high mobility two-dimensional electron gas (2DEG) at a GaAs–AlGaAs heterojunction to milliKelvin temperatures, different processing techniques and recipes for low resistance Ohmic contacts based on alloys of Au, Ni, and Ge are fabricated on these semiconductor devices. Scanning electron microscope (SEM) and Energy Dispersive X-ray (EDX) images establish that the Ohmic contacts have the same inhomogeneous microstructure observed in the literature. The unexpected result from electrical measurements of the contact resistance RC, the four-terminal resistance along the top of a single contact Rtop, and the vertical resistance RV, is that there is superconductivity in the Ohmic contact below 0.9 K. Measurements for different Ohmic contacts investigated, show some have multiple superconducting transitions, whereas others have a single transition; there is no correlation discovered between the annealing recipe and the number of transitions. I-V measurements show the superconductor is turned completely normal with a DC current of 2.1 mA and in a magnetic field, the superconductor is turned completely normal with a magnetic field of 0.15 T. This thesis speculates on the superconductor, suggesting that the Ohmic contact is a granular superconductor comprised of multiple alloys of different phases, and reviews the possible compounds that may be superconducting below 0.9 K. There is a discussion on how this superconductivity affects electrical transport measurements in similar systems such as quantum conductance, four-terminal Hall measurements and electron cooling experiments in 2DEGs below 0.1 K.

Published

2021

23. Phase transformation and transport in sulphur at high pressure and temperature

Author

Bartlett, Hannah B., McWilliams, Stewart, and Loveday, John

Subjects

high-pressure, sulphur, superconducting, H3S, thermal conductivity

Abstract

Sulphur has one of the most complex high pressure-temperature phase diagrams of the elements, with many solid phases and multiple liquid phases reported up to 40 GPa (400 kbar). The high temperature stability of solid phases is poorly understood and the melting curve above 12 GPa has been largely unstudied. As pressure and temperature increase, optical and electronic characteristics of sulphur change significantly in both solid and liquid phases. At present there are four generally accepted solid phases up to 83 GPa, above which solid sulphur becomes metallic. Sulphur is thought to be present in multiple planetary cores and is a constituent of H3S, a high pressure-temperature superconductor (TC = 203 K), so understanding its behaviour at extremes is of broad interest. In this thesis, multiple probe techniques have been used to examine phase transformations and transport properties of sulphur at high pressure-temperature conditions, including optical spectroscopy and x-ray diffraction measurements. High pressure conditions have been achieved using the diamond anvil cell, and three heating techniques have been implemented; resistive heating, near-IR (1070 nm) laser heating and mid-IR (10.6 µm) laser heating. Pressures were determined using the ruby fluorescence effect, the diamond edge scale, the equation of state of gold during x-ray studies and by comparing Raman band frequencies to the literature. Stokes to anti-Stokes intensity ratio behaviour was used to measure temperatures alongside thermal emission measurements, and a thermocouple during resistive heating experiments. Sulphur samples were heated to temperatures of ∼1900 K, and compressed to 49.9 GPa. Solid and liquid phase changes were identified using Raman spectra, optical observations, anomalies in laser power vs. temperature dependencies, and x-ray diffraction patterns. The melting curve has been extended up to 45.6 GPa, and an extensive study of the stability regions of solid phases has been made. Multiple liquid phases have been detected, exhibiting different optical absorption properties. The time-domain thermoreflectance technique was also investigated for high pressure samples heated using laser pulses to measure transport (thermal conduction).

Published

2021

24. Suspended 2D Materials: A Short Review.

Author

Dai, Yunyun, Xue, Tongtong, Han, Xu, Huang, Xinyu, Zhang, Decheng, Huang, Mengting, Yan, Jiahao, Zhao, Jinghan, Laxmi, Vijay, Liu, Liwei, Xu, Xiaolong, Wang, Yeliang, and Huang, Yuan

Subjects

OPTICAL properties, NANOFABRICATION, THERMAL properties, PHOTONICS, OPTOELECTRONICS

Abstract

In recent years, there has been a growing fascination with suspended two-dimensional (2D) materials, owing to their excellent mechanical, optical, and electronic characteristics. This surge of interest stems from the remarkable properties exhibited by these materials when they are isolated in a two-dimensional counterpart. Nanofabrication technologies provide a new platform to further explore the properties of 2D materials by suspending them to reduce the influence of substrates. In recent years, many scientists have discovered the feasibility of using suspended membranes of 2D materials in various fields, including optoelectronics and photonics. This review summarizes the recent progress in the fabrication, characterization, and applications of suspended 2D materials, focusing on critical properties such as optical and electronic properties, strain engineering, and thermal properties. This area has the potential to lead to new technologies and applications in a wide range of innovative fields. [ABSTRACT FROM AUTHOR]

Published

2023

25. Automated Determination of Critical Temperature

Author

Deshpande, Abhishek, Pardhi, Jatin, Bisen, Gokul, Kacprzyk, Janusz, Series Editor, Pal, Nikhil R., Advisory Editor, Bello Perez, Rafael, Advisory Editor, Corchado, Emilio S., Advisory Editor, Hagras, Hani, Advisory Editor, Kóczy, László T., Advisory Editor, Kreinovich, Vladik, Advisory Editor, Lin, Chin-Teng, Advisory Editor, Lu, Jie, Advisory Editor, Melin, Patricia, Advisory Editor, Nedjah, Nadia, Advisory Editor, Nguyen, Ngoc Thanh, Advisory Editor, Wang, Jun, Advisory Editor, Shakya, Subarna, editor, Balas, Valentina Emilia, editor, Kamolphiwong, Sinchai, editor, and Du, Ke-Lin, editor

Published

2022

26. Bringing near-field scanning microwave microscopy into the quantum regime

Author

Geaney, Shaun

Subjects

621.381, NSMM, Quantum, Technologies, Near-field, Scanning, Microwave, Microscopy, Single photon, Two-level systems, TLS, TLF, Resonator, Superconducting, Tuning fork, Probe, Fractal, Regime

Abstract

Near-field scanning microwave microscopy (NSMM) is a widely used scanning probe microscopy (SPM) technique. It can non-intrusively probe the material properties of a sample at the nano-scale using microwave frequency radiation. The rapid development of nanotechnology, materials and surface science underpinned by scanning probe techniques drives the demand for ever more versatile and non-invasive nano-scale analysis tools. Specifically, the development of solid-state quantum technologies has created a need for nano-scale measurement techniques that operate in the same regime as these quantum devices. However, there are very few nano-scale characterisation tools that are capable of quantum coherent interaction with samples. In particular, all NSMMs so far operate in the 'classical' regime, at high powers. To reach the quantum limit for NSMM we require (i) temperatures that are lower than the photon energy, kbT << hω and (ii) ultra-low power such that the average photon number (n) ~ 1, as is necessary for coherent interaction with a quantum system without saturating it. This work presents an ultra-low power cryogenic NSMM integrated with an atomic force microscope (AFM), to enable precise distance control. A high-quality 6 GHz superconducting resonator is used as the microwave probe. This resonator is micro-machined so that it also forms the scanning tip of the AFM. We show that the microscope is capable of obtaining nano-scale dielectric contrast down to the single microwave photon regime, up to 109 times lower power than in typical NSMMs. The microscope was designed in-house in a dilution refrigerator operating at 10 mK with a customised suspension system to minimise the effects of external mechanical vibrations. In this thesis, we evaluate the performance of this NSMM. We also discuss the remaining challenges towards developing an NSMM capable of quantum coherent interaction, an enabling tool for the development of quantum technologies in the microwave regime.

Published

2019

27. Unique Electronic Properties of the Twisted Bilayer Graphene.

Author

Wang, Mingda, Shan, Wenzhe, and Wang, Hongming

Subjects

*QUANTUM Hall effect, *ANOMALOUS Hall effect, *GRAPHENE

Abstract

Graphene is the first experimentally discovered two‐dimensional material. This article reviews the unique properties of the so‐called twisted bilayer graphene (TBG), which can be considered a superstructure formed by stacking two graphene layers with a specific twisting angle. The main topics covered by this review include the correlated insulating phase, superconducting phase, quantum anomalous Hall effect, and the corresponding theoretical analysis. In addition, the twisted multilayer graphene, considered to have better tunability than the TBG, is discussed, followed by our conclusions and proposed research fields. [ABSTRACT FROM AUTHOR]

Published

2023

28. Evidence of Superconductivity Induced by Copper Doping in NbTe2 Single Crystals.

Author

Chen, Jiafeng, Si, Jingying, Pal, Arnab, Gao, Yu, Zhang, Yifeng, Chen, Yanhong, Cao, Shixun, and Feng, Zhenjie

Subjects

*SUPERCONDUCTING transition temperature, *SUPERCONDUCTIVITY, *SINGLE crystals, *SEMIMETALS, *COPPER, *PHASE diagrams

Abstract

NbTe2 is a distorted monoclinic quasi-two-dimensional layered semimetal with superconductivity at 0.5 K. We report the investigation of the influence of Cu substitution on the superconductivity in NbTe2. Surprisingly, we found that a very small amount of Cu doing in Nb sites can greatly enhance the superconductivity of Nb1−xCuxTe2 single crystal samples. The superconducting transition temperature increases 6 times to 3 K for the optimal composition Nb0.95Cu0.05Te2, and then decreases for higher x; the superconducting transition temperature disappears when x = 0.1, which forms a dome-shaped superconducting phase diagram. [ABSTRACT FROM AUTHOR]

Published

2023

29. Preparation and Peculiar Magnetic Properties at Low Temperatures of La1.85Sr0.15CuO4 Nanofibers

Author

Shi-Long Gao, Ting-Ting Zhang, Li-Peng Qiu, Yu-Rui Zhang, Guo-Ting Cheng, Qi Liu, Wen-Peng Han, Seeram Ramakrishna, and Yun-Ze Long

Subjects

superconducting, nanofibers, La1.85Sr0.15CuO4, electrospinning, ferromagnetism, Chemistry, QD1-999

Abstract

Herein, the preparation process, morphology, structure, and magnetic properties of La1.85Sr0.15CuO4 (LSCO) cobweb-like nanofibers are reported. LSCO nanofibers with a regular grain size distribution are successfully prepared via electrospinning, followed by calcination. We conducted morphology analysis and elemental distribution using electron microscopy and energy-dispersive X-ray spectroscopy (EDS), respectively. Additionally, magnetic property testing was performed using a vibrating sample magnetometer (VSM) to confirm the superconducting properties of the samples. Interestingly, our samples exhibited a superconducting transition temperature, Tc, of 25.21 K, which showed some disparity compared to similar works. Furthermore, we observed a ferromagnetic response at low temperatures in the superconducting nanofibers. We attribute these phenomena to the effects generated by surface states of nanoscale superconducting materials.

Published

2024

30. The 16 T Dipole Development Program for FCC and HE-LHC

Author

Schoerling, D, Arbelaez, D, Auchmann, B, Bajko, M, Ballarino, A, Barzi, E, Bellomo, G, Benedikt, M, Bermudez, SI, Bordini, B, Bottura, L, Brouwer, L, Bruzzone, P, Caiffi, B, Caspi, S, Chakraborti, A, Coatanea, E, De Rijk, G, Dhalle, M, Durante, M, Fabbricatore, P, Farinon, S, Felice, H, Fernandez, A, Fernandez, IS, Gao, P, Gold, B, Gortsas, T, Gourlay, S, Juchno, M, Kashikhin, V, Kokkinos, C, Kokkinos, S, Koskinen, K, Lackner, F, Lorin, C, Loukas, K, Louzguiti, A, Lyytikainen, K, Mariotto, S, Marchevsky, M, Montenero, G, Munilla, J, Novitski, I, Ogitsu, T, Pampaloni, A, Perez, JC, Pes, C, Petrone, C, Polyzos, D, Prestemon, S, Prioli, M, Ricci, AM, Rifflet, JM, Rochepault, E, Russenschuck, S, Salmi, T, Santillana, IA, Savary, F, Scheuerlein, C, Segreti, M, Senatore, C, Sorbi, M, Statera, M, Stenvall, A, Tavian, L, Tervoort, T, Tommasini, D, Toral, F, Valente, R, Velev, G, Verweij, AP, Wessel, S, Wolf, F, Zimmermann, F, and Zlobin, AV

Subjects

FCC, Nb3Sn, superconducting, T, General Physics, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering

Abstract

A future circular collider (FCC) with a center-of-mass energy of 100 TeV and a circumference of around 100 km, or an energy upgrade of the LHC (HE-LHC) to 27 TeV require bending magnets providing 16 T in a 50-mm aperture. Several development programs for these magnets, based on Nb3Sn technology, are being pursued in Europe and in the U.S. In these programs, cos-theta, block-type, common-coil, and canted-cos-theta magnets are explored; first model magnets are under manufacture; limits on conductor stress levels are studied; and a conductor with enhanced characteristics is developed. This paper summarizes and discusses the status, plans, and preliminary results of these programs.

Published

2019

31. A Comprehensive Review for Application of Fault Current Limiters in Power Systems

Author

Wafaa Saeed Majeed, Amal Ibrahim Nasser, and Layth Tawfeeq Al -Bahrani

Subjects

superconducting, fault current limiter, non-superconducting, power system stability, optimal placement, fault ride through capability, Science

Abstract

The integration regarding various power electronic devices has led to an increase in the complexity of power systems. Limiting the fault currents is crucial for protecting these systems, the augmentation of fault reliability, and the stability. Many Faults Current Limiters (FCLs) were used in power systems because they quickly and effectively fault current limiters. The presented work gives a thorough literature review regarding the use of various FCL types in the power systems. The non-superconducting and superconducting FCL applications have been divided into five categories: (a) application in transmission, distribution and generation networks; (b) applications in the systems of alternating current (AC)/direct current (DC); (c) applications in the integration of renewable sources of energy; (d) applications in the distributed generation (DG); (e) applications for improving stability, reliability, and fault ride through capabilities. With examples of their practical implementation in various nations, impact, modeling, and control approaches of various FCLs in the power systems have been shown. With the alteration of its structures, appropriate control design, and optimal placement recommendations have been given in order to enhance performance regarding FCLs in the power systems. In order to incorporate the continuing research advances in practical systems, industry and researchers working on power system stability concerns can benefit greatly from this study.

Published

2023

32. Pressure-Induced Reversible Local Structural Disorder in Superconducting AuAgTe 4.

Author

Zamyatin, Dmitry A., Pankrushina, Elizaveta A., Streltsov, Sergey V., and Ponosov, Yuri S.

Subjects

*LATTICE dynamics, *VIBRATIONAL spectra, *PHASE transitions, *ELECTRON-phonon interactions, *RAMAN spectroscopy, *PHONON scattering

Abstract

Here, we report results of the investigation of the lattice dynamics of the sylvanite mineral AuAgTe4 in a wide temperature and pressure range by Raman spectroscopy, together with the first-principle calculations. At ambient pressure, the experimental spectrum agrees well with the calculation data. The temperature behavior of the phonon self-energies (frequencies and linewidths) are described by an anharmonic mechanism and imply negligible contributions of electron–phonon interaction at low temperatures. A structural phase transition was recorded in the pressure range of 4–6 GPa, which is in accordance with theoretical predictions. At higher pressures, evidence of local structural disorder was found that made it possible to experimentally observe the spectrum of the density of vibrational states of AuAgTe4, which becomes superconducting under pressure. [ABSTRACT FROM AUTHOR]

Published

2023

33. Superconducting Energy Gap in Hole-Doped Graphene Beyond the Migdal's Theory.

Author

KACZMAREKA, A. Z. and DRZAZGA-SZCZESNIAK, E. A.

Subjects

*BAND gaps, *GRAPHENE, *ELECTRON-phonon interactions, *SUPERCONDUCTIVITY, *DOPING agents (Chemistry)

Abstract

In this work, we analyze the impact of non-adiabatic effects on the superconducting energy gap in hole-doped graphene. By using the Eliashberg formalism beyond Migdal's theorem, we present that non-adiabatic effects strongly influence the superconducting energy gap in the exemplary boron-doped graphene. In particular, non-adiabatic effects, as represented by the first-order vertex corrections to the electron-phonon interaction, supplement the Coulomb depairing correlations and suppress the superconducting state. In summary, the obtained results confirm previous studies on superconductivity in two-dimensional materials and show that the corresponding superconducting phase may be notably affected by non-adiabatic effects. [ABSTRACT FROM AUTHOR]

Published

2023

34. Phase Diffusion in Low- E J Josephson Junctions at Milli-Kelvin Temperatures.

Author

Lu, Wen-Sen, Kalashnikov, Konstantin, Kamenov, Plamen, DiNapoli, Thomas J., and Gershenson, Michael E.

Subjects

JOSEPHSON junctions, QUANTUM computing, SUPERCONDUCTING circuits, QUBITS, CIRCUIT elements, TEMPERATURE

Abstract

Josephson junctions (JJs) with Josephson energy E J ≲ 1 K are widely employed as non-linear elements in superconducting circuits for quantum computing operating at milli-Kelvin temperatures. In the qubits with small charging energy E C ( E J / E C ≫ 1 ), such as the transmon, the incoherent phase slips (IPS) might become the dominant source of dissipation with decreasing E J . In this work, a systematic study of the IPS in low- E J JJs at milli-Kelvin temperatures is reported. Strong suppression of the critical (switching) current and a very rapid growth of the zero-bias resistance due to the IPS are observed with decreasing E J below 1 K. With further improvement of coherence of superconducting qubits, the observed IPS-induced dissipation might limit the performance of qubits based on low- E J junctions. These results point the way to future improvements of such qubits. [ABSTRACT FROM AUTHOR]

Published

2023

35. Electrodeposition of ReMo alloys.

Author

Liu, Quanhong and Huang, Qiang

Subjects

*MOLYBDENUM alloys, *ALLOY plating, *SUPERCONDUCTORS, *SUPERCONDUCTIVITY, *ELECTROPLATING, *CITRATES

Abstract

The electrodeposition of superconducting ReMo alloys is investigated using highly concentrated electrolytes with acetate, citrate, and the two oxometallate anions, MoO 4 2− and ReO 4 −. The effects of applied deposition current, the concentrations of acetate, citrate, and metal source in the electrolyte on the film composition, faraday efficiency as well as the partial current densities of Re and Mo are systematically studied. A hybrid complex species, such as (MoO 4 2−)(ReO 4 −)(HCit3−) 2 and its partially reduced form, is proposed to form and mediate the co-deposition reaction. The morphology and superconductivity of alloy films are characterized using microscopy and cryogenic four-probe measurements. The electrodeposited ReMo alloy films maintain the same amorphous grain structure and the same enhanced superconducting transition temperature as pure Re films. [ABSTRACT FROM AUTHOR]

Published

2024

36. Conceptual design and assessment of turboelectric and hybrid electric propulsion system architectures for civil transport aircraft

Author

Tashie-Lewis, Bernard Chukwudi, Laskaridis, Panagiotis, Miller, Paul, and Husband, Paul

Subjects

DC, TeDP, HeP, HeDP, HTS, superconducting, hydrogen, battery, energy storage, propulsor, propellor, gas turbine, CADI, ducted fan

Abstract

To achieve ambitious future environmental targets for aircraft set out by organisations such as NASA and the European Union, turboelectric distributed propulsion (TeDP) has been proposed as a novel concept that has the potential to achieve these targets by significantly improving integrated propulsion-airframe performance. Realising TeDP as a technology option brings into play a number of design and development challenges due to the highly integrated natured of TeDP-airframe configurations, low technology-readiness-levels of key enabling technologies and new modes of operation opened up by shift to a more electric architecture. In tackling these challenges a multidisciplinary and integrated method to assess the benefits and challenges of turboelectric and hybrid-electric propulsion system configurations by considering the effect of aircraft size, mission specifications, airframe, electrical system, energy storage, propulsor architecture and gas turbine architecture was created. The method created was used in the assessment of turboelectric and hybrid electric performance for a regional transport aircraft and a medium haul transport aircraft. For the regional role the employment of a DC hybrid superconducting turboelectric architecture managed to achieve 16.7% block fuel saving and 3.23% total energy consumption saving over a baseline turboprop aircraft at 600 n.mi range. Driving performance benefits was increased duration of mission time batteries spend discharging at relatively high battery power rating which overcomes weight penalties from installation of electric machinery. For medium haul role the employment of a geared hybrid electric architecture managed to achieve a 3.07% block fuel saving over a baseline turbofan aircraft at 900 n.mi range. Driving performance benefit for the mission was increased battery-operative-cruise time at relatively high battery power rating overcoming aircraft weight penalty and electric machinery installation weight penalty. Despite fuel burn reduction, hybrid electric aircraft consumes more energy than a baseline configuration primarily due to utilisation of additional energy from battery pack.

Published

2018

37. Temperature and power characteristics of quarter-wavelength superconducting coplanar waveguide resonator

Author

Huilong Yu, Lingxiao Jing, Tao Hua, and Weiwei Xu

Subjects

Superconducting, Coplanar waveguide resonator, Transmission characteristics, Science, Technology

Abstract

Abstract A quarter wavelength superconducting aluminum film coplanar waveguide resonator with a high-quality factor was designed and fabricated. Furthermore, its resonant frequency and quality as a function of temperatures and exciting powers were investigated. The experimental results showed that the resonance frequency decreases about 1% with the increase of temperature from 50 mk to 1 K, and the load quality factor of the resonator also decreases. The resonant frequency decreases with power from − 120 to − 70 dBm. The quality factor increases with increased excitation power due to the loss decreases and nonlinearity. The results are consistent with the theoretical analysis of the surface impedance model.

Published

2022

38. Status of the 16 T dipole development program for a future hadron collider

Author

Tommasini, D, Arbelaez, D, Auchmann, B, Bajas, H, Bajko, M, Ballarino, A, Barzi, E, Bellomo, G, Benedikt, M, Bermudez, SI, Bordini, B, Bottura, L, Brower, L, Buzio, M, Caiffi, B, Caspi, S, Dhalle, M, Durante, M, DeRijk, G, Fabbricatore, P, Farinon, S, Ferracin, P, Gao, P, Gourlay, S, Juchno, M, Kashikhin, V, Lackner, F, Lorin, C, Marchevsky, M, Marinozzi, V, Martinez, T, Munilla, J, Novitski, I, Ogitsu, T, Ortwein, R, Perez, JC, Petrone, C, Prestemon, S, Prioli, M, Rifflet, JM, Rochepault, E, Russenschuck, S, Salmi, T, Savary, F, Schoerling, D, Segreti, M, Senatore, C, Sorbi, M, Stenvall, A, Todesco, E, Toral, F, Verweij, AP, Wessel, S, Wolf, F, and Zlobin, AV

Subjects

Future circular collider, superconducting, Nb3Sn, T, General Physics, Electrical and Electronic Engineering, Condensed Matter Physics, Materials Engineering

Abstract

A next step of energy increase of hadron colliders beyond the LHC requires high-field superconducting magnets capable of providing a dipolar field in the range of 16 T in a 50-mm aperture with accelerator quality. These characteristics could meet the requirements for an upgrade of the LHC to twice the present beam energy or for a 100-TeV center of mass energy future circular collider. This paper summarizes the activities and plans for the development of these magnets, in particular within the 16 T Magnet Technology Program, the WP5 of the EuroCirCol, and the U.S. Magnet Development Program.

Published

2018

39. JBNN: A Hardware Design for Binarized Neural Networks Using Single-Flux-Quantum Circuits.

Author

Fu, Rongliang, Huang, Junying, Wu, Haibin, Ye, Xiaochun, Fan, Dongrui, and Ho, Tsung-Yi

Subjects

*INDUSTRIAL capacity, *JOSEPHSON junctions, *COLUMNS, *SUPERCONDUCTIVITY, *HARDWARE, *SUPERCONDUCTING circuits

Abstract

As a high-performance application of low-temperature superconductivity, superconducting single-flux-quantum (SFQ) circuits have high speed and low-power consumption characteristics, which have recently received extensive attention, especially in the field of neural network inference accelerations. Despite these promising advantages, they are still limited by storage capacity and manufacture reliability, making them unfriendly for feedback loops and very large-scale circuits. The Binarized Neural Network (BNN), with minimal memory requirements and no reliance on multiplication, is undoubtedly an attractive candidate for implementing inference hardware using SFQ circuits. This work presents the first SFQ-based Binarized Neural Network inference accelerator, namely JBNN, with a new representation to binarize weights and activation variables. Every SFQ gate is essentially a pipeline stage, making conventional design methods of the accumulator unsuitable for SFQ circuits. So an SFQ-based accumulative parallel counter using SFQ logic cells including T1, OR, and AND is designed to realize the accumulation, where the data size is reduced to a quarter after passing the XNOR column and the AU layer, largely declining the hardware cost. Our evaluation shows that the proposed design outperforms a cryogenic CMOS-based BNN accelerator design running at 77K by 70.92 times while maintaining 97.89% accuracy on the MNIST benchmark dataset. Without the cooling cost, the power efficiency increases up to 929.18 times. [ABSTRACT FROM AUTHOR]

Published

2022

40. The Classicality and Quantumness of the Driven Qubit–Photon–Magnon System.

Author

Alotaibi, Maged Faihan, Khalil, Eied Mahmoud, Abd-Rabbou, Mahmoud Youssef, and Marin, Marin

Subjects

*MAGNONS, *CAVITY resonators, *RESONATORS

Abstract

The hybrid architecture of the driven qubit–photon–magnon system has recently emerged as a promising candidate for novel quantum technologies. In this paper, we introduce the effective wave-function of a superconducting single qubit and a magnon mode contained within a cavity resonator and an external field. The non-classicality of the magnon and resonator modes are investigated by using the negative values of the Wigner function. Additionally, we discuss the non-classicality of the qubit state via the Wigner–Yanase skew information. We find that the mixture angle of the qubit–resonator plays a controllable role in non-classicality. However, the strength of the magnon–photon increases the non-classical behaviour of the system. [ABSTRACT FROM AUTHOR]

Published

2022

41. Epoxy IR Filters for Superconducting Resonators.

Author

Spahn, G., Kurinsky, N., Lewis, S., Bowring, D., and Hollister, M.

Subjects

*SUPERCONDUCTING resonators, *RESONATOR filters, *EPOXY resins, *COAXIAL cables, *QUALITY factor, *SUBSTRATE integrated waveguides, *WHISPERING gallery modes, *INFRARED radiation

Abstract

Infrared radiation leakage through dielectrics in coaxial cabling can create unwanted quasiparticles in superconducting resonators if allowed to reach devices unattenuated. Modern experimental setups commonly incorporate epoxy-based filter blocks on readout and control lines in order to mitigate this effect; however, most of these multi-channel designs require specialized mounting hardware. This investigation details the design and construction of single-channel inline infrared filters, and finds that their installation in the readout system for an aluminum resonator increased its quality factor by an average of 12% across a range of operating temperatures and powers. The option to incorporate general-purpose inline filters instead of designing custom filter blocks and mounts should prove more convenient for many newer experiments. [ABSTRACT FROM AUTHOR]

Published

2022

42. Causes and Consequences of Ordering and Dynamic Phases of Confined Vortex Rows in Superconducting Nanostripes.

Author

McNaughton, Benjamin, Pinto, Nicola, Perali, Andrea, and Milošević, Milorad V.

Subjects

*QUANTUM electronics, *MAGNETIC fields, *SUPERCONDUCTING circuits, *ELECTRIC potential, *PHASE diagrams, *SPHEROMAKS, *SUPERCONDUCTIVITY

Abstract

Understanding the behaviour of vortices under nanoscale confinement in superconducting circuits is important for the development of superconducting electronics and quantum technologies. Using numerical simulations based on the Ginzburg–Landau theory for non-homogeneous superconductivity in the presence of magnetic fields, we detail how lateral confinement organises vortices in a long superconducting nanostripe, presenting a phase diagram of vortex configurations as a function of the stripe width and magnetic field. We discuss why the average vortex density is reduced and reveal that confinement influences vortex dynamics in the dissipative regime under sourced electrical current, mapping out transitions between asynchronous and synchronous vortex rows crossing the nanostripe as the current is varied. Synchronous crossings are of particular interest, since they cause single-mode modulations in the voltage drop along the stripe in a high (typically GHz to THz) frequency range. [ABSTRACT FROM AUTHOR]

Published

2022

43. 超导量子芯片集成技术概述.

Author

郑伟文, 李晓伟, 熊康林, and 冯加贵

Abstract

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

Published

2022

44. Casimir Effect between Superconducting Plates in the Mixed State

Author

Norio Inui

Subjects

Casimir effect, superconducting, quantum fluctuations, quantum magnetic flux, Physics, QC1-999

Abstract

The Casimir effect between type-II superconducting plates in the coexisting phase of a superconducting phase and a normal phase is investigated. The dependence of the optical conductivity of the superconducting plates on the external magnetic field is described in terms of the penetration depth of the incident electromagnetic field, and the permittivity along the imaginary axis is represented by a linear combination of the permittivities for the plasma model and Drude models. The characteristic frequency in each model is determined using the force parameters for the motion of the magnetic field vortices. The Casimir force between parallel YBCO plates in the mixed state is calculated, and the dependence on the applied magnetic field and temperature is considered.

Published

2021

45. Development of ROACH firmware for microwave multiplexed X-ray TES microcalorimeters

Author

Gard, J.

Published

2016

46. Finite element simulation and structure optimization of HTS solenoid

Author

Menglong Cong, Shanshan Zhang, Xueyan Chen, and Kunpeng Zhou

Subjects

superconducting, solenoid magnet, pancake coil, critical current, finite element method, Technology

Abstract

When the current passing through a high temperature superconducting (HTS) coil that exceeds a critical value, the properties of the materials which make up the coil will fail, generating large amounts of heat and even causing serious accidents. Aiming at the above safety problem, this paper took three solenoid magnets with different structures as the object, and conducted a simulation study on their electromagnetic performance through finite element method (FEM). The magnetic field intensity H was taken as the dependent variable of the control equations of the physical field. With the aid of the partial differential equation (PDE) interface of the simulation software used, the control equations were easily constructed. The pancake coil wound by many turns of ribbon conductors was abstracted as a bulk-like conductor with the same cross-sectional area. The main idea of this equivalent replacement is to simplify the internal structure of the device without affecting its electromagnetic behavior, which can accelerate the convergence speed of the simulation process and reduce the CPU burden. Models of solenoid magnets with rectangular, trapezoidal and inverted trapezoidal cross sections were established by stacking many pancake coils. The simulation results corresponding to these models show that the solenoid magnet with trapezoidal cross-section has the largest critical current and most uniform density distribution. Such advantages not only reduce the risk of superconducting material failure due to overheating at both ends, but also fully exploit the current carrying capacity of the coil in the middle area of the solenoid.

Published

2022

47. Literature Review of Suspension Systems for Superconducting Elements

Author

Luca Piacentini, Luca Dassa, Diego Perini, Andris Ratkus, Toms Torims, and Stefano Uberti

Subjects

superconducting, cold mass, supports, suspension, rotating machine, medical machine, Mechanical engineering and machinery, TJ1-1570

Abstract

When designing suspension systems for superconducting elements, the primary challenge is to strike a balance between limiting the heat load to the cold mass and ensuring the proper mechanical resistance and/or stiffness of the system. This trade-off often leads engineers to choose from a limited set of materials and supporting architectures. The aim of this study is to provide an overview of the different overall designs. Scientific articles were searched within the Google Scholar database using advanced search operators to combine a defined set of keywords. Among the architectures found, the “multi-post” solution and the “8-support” solution are the two most commonly chosen classes. Additionally, a recurrent pattern for the supporting system of superconducting cavities has been identified. The choice of architecture can be correlated with the characteristics of the superconducting element being supported, such as its mass, length, and stiffness. Furthermore, the review provides a conceptual analysis of the possibility of extending these designs to the unconventional environment of rotating machines.

Published

2023

48. Suspended 2D Materials: A Short Review

Author

Yunyun Dai, Tongtong Xue, Xu Han, Xinyu Huang, Decheng Zhang, Mengting Huang, Jiahao Yan, Jinghan Zhao, Vijay Laxmi, Liwei Liu, Xiaolong Xu, Yeliang Wang, and Yuan Huang

Subjects

suspended, two-dimensional materials, nanofabrication, light enhancement, superconducting, Crystallography, QD901-999

Abstract

In recent years, there has been a growing fascination with suspended two-dimensional (2D) materials, owing to their excellent mechanical, optical, and electronic characteristics. This surge of interest stems from the remarkable properties exhibited by these materials when they are isolated in a two-dimensional counterpart. Nanofabrication technologies provide a new platform to further explore the properties of 2D materials by suspending them to reduce the influence of substrates. In recent years, many scientists have discovered the feasibility of using suspended membranes of 2D materials in various fields, including optoelectronics and photonics. This review summarizes the recent progress in the fabrication, characterization, and applications of suspended 2D materials, focusing on critical properties such as optical and electronic properties, strain engineering, and thermal properties. This area has the potential to lead to new technologies and applications in a wide range of innovative fields.

Published

2023

49. The effect of in situ irradiation on the superconducting performance of REBa2Cu3O7−δ-coated conductors

Author

Iliffe, Will, Adams, Kirk, Peng, Nianhua, Brittles, Greg, Bateman, Rod, Reilly, Aidan, Grovenor, Chris, and Speller, Susannah

Published

2023

50. 单光子探测器的研究进展.

Author

程碑彤, 代 千, 谢修敏, 徐 强, 张 杉, and 宋海智

Abstract

Copyright of Laser Technology is the property of Gai Kan Bian Wei Hui and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022