Wire Structures Research Articles

The influence of Sm2O3 dopant on structure, morphology and transport critical current density of MgB2 wires investigated by using the transmission electron microscope

The influence of Sm2O3 dopant on structure, morphology and transport critical current density of MgB2 wires investigated by using the transmission electron microscope

Coordination and Structural Control of Trinuclear Ruthenium Clusters Using Organic Ligands at HOPG Surface

Controlling the self-assembly and nanoarchitectures of metal complexes at the molecular scale is essential for the development of new functional materials and devices. Since two-dimensional (2D) sheets consisting of metal complexes can be designed and controlled with various bonding modes, geometric structures, and chemical functions, they have been studied using various approaches by selecting metal ions and organic ligands. Trinuclear metal clusters contain three metal ions in one complex and are expected to be building blocks for the formation of 2D sheets of metal complexes by selecting their shape and axial ligands. In this study, a trinuclear cluster of ruthenium ions, Ru3O(EtCOO)6(CO)(THF)2:1, was used as the core to form nanostructures on highly oriented pyrolytic graphite (HOPG) substrates via axial ligand exchange with 1,4-Di (4-pyridyl) benzene:2 and 4,4’-di(4-pyridyl) biphenyl: 3. The adlayer structures and electrochemical properties of the nanoarchitectures were investigated by atomic force microscopy (AFM) and cyclic voltammetry (CV). In the experimental procedure, powders of 1, 2, and 3 were dissolved in methanol (MeOH) and tetrahydrofuran (THF), respectively, and a 0.78 µM solution was prepared. A predetermined amount of this was cast on HOPG, dried to form a thin film, and the thin film was observed in air using AFM. Next, equal amounts of 1 and 2 and 1 and 3 solutions were mixed in each solvent, and after heating a water bath at 60°C for 1 h, thin films were prepared in the same manner and observed by AFM. Ultraviolet–visible (UV-vis) absorption spectra and electrochemical measurements by CV were performed before and after heating the mixed solutions. First, in the AFM image of the thin film prepared by casting the MeOH mixture of 1 and 2, two stripe-like domains with different heights were observed, which matched the heights of the structures obtained in the AFM images of the single-domain formation of 1 and 2. In addition, no new absorption peaks were observed in the UV-vis absorption spectrum after mixing the solution; it was inferred that 1and 2 did not exchange ligands. However, when the mixed solution was heated in a water bath for 1 h, a few striped domains were observed, and a new ring-like structure was formed. The CV results also supported the change in the AFM images and absorption spectra after heating the solution. Before heating the mixed solution, a small redox peak was observed around 0.8 V, whereas after the warm bath, a large redox peak was observed around 0.6 V. A dramatic change in the magnitude of the current density was observed, indicating a significant improvement in conductivity. These results suggest that heating the mixed solution replaced THF ligand 1 with 2, forming a cyclic structure consisting of 1 and 2. When the same experiment was carried out in THF solution, a different structure was observed from that of the methanol solution, and a one-dimensional (1D) molecular wire structure was formed after heating the water bath. The absorption spectra and CV results also supported that ligand exchange occurred in the 1D wire structure, revealing the solvent dependence of the nanoarchitecture. When 3 was used as the axial ligand, larger structures were formed compared to 2, and one-dimensional wire structures of several micrometers were observed in the THF solution after the warm bath. Larger current densities and peak separations are also observed in the voltammograms. Thus, the length dependence of the organic ligand for the nanoarchitecture formation on the HOPG surface was demonstrated. Figure 1

Obtaining Symmetrical Gradient Structure in Copper Wire by Combined Processing

Traditionally, structural wire is characterized by a homogeneous microstructure, where the average grain size in different parts of the wire is uniform. According to the classical Hall–Petch relationship, a homogeneous polycrystalline metal can be strengthened by decreasing the average grain size since an increase in the volume fraction of grain boundaries will further impede the motion of dislocations. However, a decrease in the grain size inevitably leads to a decrease in the ductility and deformability of the material due to limited dislocation mobility. Putting a gradient microstructure into the wire has promising potential for overcoming the compromise between strength and ductility. This is proposed a new combined technology in this paper in order to obtain a gradient microstructure. This technology consists of deforming the wire in a rotating equal-channel step die and subsequent traditional drawing. Deformation of copper wire with a diameter of 6.5 mm to a diameter of 5.0 mm was carried out in three passes at room temperature. As a result of such processing, a gradient microstructure with a surface nanostructured layer (grain size ~400 nm) with a gradual increase in grain size towards the center of the wire was obtained. As a result, the microhardness in the surface zone was 1150 MPa, 770 Mpa in the neutral zone, and 685 MPa in the central zone of the wire. Such a symmetrical spread of microhardness, observed over the entire cross-section of the rod, is a direct confirmation of the presence of a gradient microstructure in deformed materials. The strength characteristics of the wire were doubled: the tensile strength increased from 335 MPa to 675 MPa, and the yield strength from 230 MPa to 445 MPa. At the same time, the relative elongation decreased from 20% to 16%, and the relative contraction from 28% to 23%. Despite the fact that the ductility of copper is decreased after cyclic deformation, its values remain at a fairly high level. The validity of all results is confirmed by numerous experiments using a complex of traditional and modern research methods, which include optical, scanning, and transmission microscopy; determination of mechanical properties under tension; and measurement of hardness and electrical resistance. These methods allow reliable interpretation of the fine microstructure of the wire and provide information on its strength, plastic, and electrical properties.

Hierarchical Nanowire Host Material for High‐Areal‐Capacity All‐Solid‐State S/SeS2 Batteries

AbstractAll‐solid‐state sulfur batteries (ASBs) suffer from electrical and ionic conduction problems due to the insulating sulfur. By comparing three host materials with different structural characteristics, herein, carbon nanotubes (CNTs) decorated with a conductive metal sulfide (CoMoS2@CNT) is demonstrated, designed to host sulfur and exchange both Li‐ions and electrons, effectively. In this hierarchical wire structure, porous CoMoS2 nanosheets form close interfaces with sulfur, and the CNT core directly transfers electrons to the sulfur‐impregnated CoMoS2. Simultaneously, the solid electrolyte positioned on the outer region of the nanowire material ensures facile Li‐ion conduction to the sulfur‐impregnated CoMoS2. An ASB featuring a CoMoS2@CNT host material with a sulfur loading of 3 mg cm−2 exhibits a high‐areal‐capacity of 4.5 mAh cm−2 at a current density of 2.5 mA cm−2, while retaining 79.4% of its initial capacity after 300 cycles. When sulfur is replaced with SeS2 to further reinforce the charge conduction properties, all‐solid‐state SeS2 batteries (ASeS2Bs) with an extremely high‐areal‐capacity of 16.3 mAh cm−2 retain 99.3% of their initial capacities after 60 cycles at 60 °C. This study provides guidelines for the design principles of cathode composites for the ASBs and ASeS2Bs through multiangle comparative analysis.

ID: 344721 Removal Procedure of a Helical Wire Structure Electrode from Benchtop and Chronic Porcine Models

ID: 344721 Removal Procedure of a Helical Wire Structure Electrode from Benchtop and Chronic Porcine Models

Phonon growth characteristics in one-dimensional cylindrical quantum wires at low lattice temperatures

The phonon growth characteristics in a cylindrical quantum wire structure has been theoretically analysed here under the condition of low lattice temperature. The present theory takes into account the effects of finite barrier height, energy band non-parabolicity of the material and the non-zero values of the transverse components of the phonon wave vector. At the low lattice temperatures again, the interaction of the non-equilibrium electrons with acoustic phonons becomes inelastic and consequently the phonon distribution cannot be approximated by the simple equipartition law. Hence the full form of the Bose-Einstein distribution for the phonon ensemble is taken into consideration. The numerical results that follow from the present theory for the wire samples of GaAs/Ga0.7Al0.3As and Ga0.47In0.53As/InP turn out to be quite different from what follows in the traditional simplified framework.

Flexible generation of OAM mode reconfigurable beams and spinning OAM beams based on active induced magnetism Huygens' metasurface.

Orbital angular momentum (OAM) beams have demonstrated significant potential in the fields of communication, imaging and quantum information science. In particular, active OAM metasurfaces enable flexible and on-demand control of OAM beams without altering their structures, significantly enriching the applications of OAM beams. However, due to the limitations of electrode wiring and unit structure efficiency, most existing active metasurface designs are reflective, hindering the further development of this field. Here, we propose an active induced magnetism Huygens' metasurface to overcome these limitations. We demonstrate that transmissive and high-efficiency OAM mode reconfigurable beams of topological charge l = -1 or l = +1, as well as spatiotemporally modulated spinning OAM harmonic beam of topological charge l = +1 can be generated on-demand. The findings of this study provide a novel approach to achieve more flexible and diversified OAM beamforming, addressing the evolving demands of various OAM-related applications.

Shock wave generated by composite energetic material driven by electrical non-penetrating wire explosion plasma.

Underwater shock wave technology can realize dynamic rock fracture, which is helpful to increase oil and gas reservoir permeability. It can realize the efficient exploitation of medium and low maturity oil and gas resources. In practical application, the shock wave parameters require not only high intensity but also safety and controllability. To meet these requirements, insensitive composite energetic materials driven by electrical wire explosion plasma were proposed, which is one of the most promising methods. However, when in use, the load assembly process containing wires and energetic materials is complex. In this paper, a new type of energetic material load is proposed, using non-penetrating wire to drive composite energetic material. It can simplify the production process of the energetic load and produce acceptable shock wave parameters. The test results show that both the energy deposition of the wire and the shock wave intensity decrease under a non-penetrating wire structure. However, the shock wave intensity is still higher than that of the underwater electrical wire explosion. Based on schlieren diagnosis, it is found that the composite energetic material is gradually driven, and the energy release is not concentrated. In addition, the "non-wire" structure driving condition was discussed in contrast. Under this condition, the process of ionization channel establishment in composite energetic materials is random. The shock wave intensity is weak because the composite energetic material is in the process of slow detonation.

Influence of new wire structure on AC loss of high-temperature superconducting cables

Influence of new wire structure on AC loss of high-temperature superconducting cables

Radial force and wire structure determine the onset of covered self-expandable metal stent migration in endoscopic ultrasound-guided hepaticogastrostomy: Measurement of sliding-resistance force using a porcine model.

Self-expandable metal stent (SEMS) migration after endoscopic ultrasound-guided hepaticogastrostomy (EUS-HGS) is a severe complication. The migration risk could be related to the surface friction of SEMS, assumed to be affected by the wire structure and mechanical properties, including radial force (RF); however, their relevance remains unclear. This experimental study aimed to assess the mechanical properties of SEMS involved in the onset of stent migration by measuring the sliding-resistance force (SF) as the SEMS moves through the stomach wall. The SF of seven types of 8-mm diameter SEMS (four braided and three laser-cut types) and porcine stomach wall was measured with a universal testing machine. The SF of each SEMS was measured three times, and the average maximum SF (SFmax) was used for analysis. The correlation between SFmax and RF of each SEMS was evaluated. SFmax and RF showed a very strong positive correlation (r = 0.92). Compared to the regression line predictions in the scatter plots of SFmax and RF, the SFmax of laser-cut and braided type SEMSs had positive and negative residuals, respectively. Selecting a laser-cut type SEMS with a higher RF may more effectively prevent the onset of stent migration against the stomach wall in EUS-HGS.

Processing of fully dense and high conductivity W[sbnd]20Cu composite via copper melt infiltration into a pressed tungsten wire skeleton

The current study proposed melt infiltration into entangled pressed wire as a proper method for rapid and energy-efficient production of tungsten‑copper composites. The process includes wire packing through different strategies, pressing, and infiltration steps. First, a predesigned wire structure through different strategies of simple, spiral, cylindrical, and spherical is packed and pressed to form a permeable tungsten skeleton. Then, by infiltrating molten copper under a dry hydrogen atmosphere into the porous preforms, the W20Cu composite is fabricated and characterized. An almost fully dense sample with excellent hardness of 238.1 HV1 and high conductivity of 58.64% IACS in W20Cu composite was achieved. These values are almost 25% and 50% higher than that from the conventional melt infiltration method, respectively. It was seen that the packing strategy is so effective in achieving the best properties where the processed composite by spherical packing strategy exhibits better density, conductivity, and hardness than the sample produced via the other three packing strategies. However, all the properties of the melt infiltration into entangled pressed wire processed composite via all packing strategies are higher than those processed via conventional methods. These excellent properties could be attributed to the mostly bonded tungsten phase, high purity, pore-free, and suitable distribution of tungstens which are a result of this process characteristics. Besides, lower cycle time and energy consumption are other advantages of the new process compared to conventional melt infiltration via powder metallurgy. This approach presents a promising prospect for future industrial applications.

Study of the structure of filler composite wire for surfacing wear-resistant layers

Study of the structure of filler composite wire for surfacing wear-resistant layers

Utilizing CNN to predict homogeneous thermo-mechanical properties of conductive layers for reliability numerical analysis in electronics

This study explores the application of Convolutional Neural Networks (CNN) in predicting the partitioned homogeneous properties (PHPs) of electronic product wiring structures, aiming to enhance the efficiency of reliability analysis through Finite Element Analysis (FEA). A systematic and novel method was developed to generate the input partitioned wiring diagram image sets that foster model generalization and universality. The performance of the CNN-based approach was assessed through regression analysis by employing a leave-one-out cross-validation (LOOCV) approach across three PCBs. Additionally, the predicted PHPs of one of the PCBs were applied in product-level FEA to validate their reliability, further demonstrating the practical applicability of the CNN-based method. The results demonstrate that a well-trained CNN model can accurately predict the properties of previously unencountered wiring structures, thereby facilitating direct application in product-level reliability FEA and improving the efficiency of reliability assessment. Furthermore, efficiency evaluation revealed that the CNN-based method offers significant advantages in terms of time and cost economy compared to the mesoscopic FEA method in determining, highlighting its potential for broader application in electronic product reliability analysis. The findings provide preliminary insights and propose strategies to enhance the applicability of CNN methods in this domain, ultimately aiming to improve the efficiency and reduce costs in reliability assessments, thereby streamlining the overall product development process.

Nuclear Magnetic Resonance Chemical Shift as a Probe for Single‐Molecule Charge Transport

AbstractExisting modelling tools, developed to aid the design of efficient molecular wires and to better understand their charge‐transport behaviour and mechanism, have limitations in accuracy and computational cost. Further research is required to develop faster and more precise methods that can yield information on how charge transport properties are impacted by changes in the chemical structure of a molecular wire. In this study, we report a clear semilogarithmic correlation between charge transport efficiency and nuclear magnetic resonance chemical shifts in multiple series of molecular wires, also accounting for the presence of chemical substituents. The NMR data was used to inform a simple tight‐binding model that accurately captures the experimental single‐molecule conductance values, especially useful in this case as more sophisticated density functional theory calculations fail due to inherent limitations. Our study demonstrates the potential of NMR spectroscopy as a valuable tool for characterising, rationalising, and gaining additional insights on the charge transport properties of single‐molecule junctions.

Nuclear Magnetic Resonance Chemical Shift as a Probe for Single-Molecule Charge Transport.

Existing modelling tools, developed to aid the design of efficient molecular wires and to better understand their charge-transport behaviour and mechanism, have limitations in accuracy and computational cost. Further research is required to develop faster and more precise methods that can yield information on how charge transport properties are impacted by changes in the chemical structure of a molecular wire. In this study, we report a clear semilogarithmic correlation between charge transport efficiency and nuclear magnetic resonance chemical shifts in multiple series of molecular wires, also accounting for the presence of chemical substituents. The NMR data was used to inform a simple tight-binding model that accurately captures the experimental single-molecule conductance values, especially useful in this case as more sophisticated density functional theory calculations fail due to inherent limitations. Our study demonstrates the potential of NMR spectroscopy as a valuable tool for characterising, rationalising, and gaining additional insights on the charge transport properties of single-molecule junctions.

The influence of hydrogen diffusion in the structure of NiTi wires on their behavior during the cyclic loading

The influence of hydrogen diffusion in the structure of NiTi wires on their behavior during the cyclic loading

Continuous high viscosity biphasic liquid separation

Enhancing the efficiency of separation in high-viscosity biphasic liquid purification processes can significantly reduce energy consumption and costs. This study has developed a co-axial biphasic liquid separator that can continuously and instantaneously separate two-phase mixtures with viscosities up to 2000 mPa∙s at room temperature, to meet real industrial needs. This co-axial biphasic liquid separator uses a special helix wire structure that separates the two-phase fluids based on the difference in surface tension, unaffected by the viscosity of the liquids. In experiments with PMMA-toluene-water mixtures, the flow rate can reach up to 4000 μl/min, with PMMA recovery rates consistently above 83.6 %, and as high as 91.5 %. In experiments with undiluted heavy oil–water, a purity of up to 87.58 % was achieved for heavy oil, and for diluted heavy oil, the purity even reached as high as 92.15 %. The separator demonstrated remarkable universality and durability, maintaining stable and high-purity biphasic separation across varying flow rates, through 15 cycles of repeated use, and during prolonged operations of up to one hour, without any system failures. The co-axial biphasic liquid separator developed in this study is currently the only few microseparator in continuous processes capable of separating liquids with viscosities over 2100 mPa∙s, and it could decrease the cost of relevant process development in industrial setups, realizing the vision of green manufacturing.

Investigation of Layered Structure Formation in MgB2 Wires Produced by the Internal Mg Coating Process under Low and High Isostatic Pressures.

Currently, MgB2 wires made by the powder-in-tube (PIT) method are most often used in the construction and design of superconducting devices. In this work, we investigated the impact of heat treatment under both low and high isostatic pressures on the formation of a layered structure in PIT MgB2 wires manufactured using the Mg coating method. The microstructure, chemical composition, and density of the obtained superconductive wires were investigated using scanning electron microscopy (SEM) with an energy-dispersive X-ray spectroscopy (EDS) analyzer and optical microscopy with Kameram CMOS software (version 2.11.5.6). Transport measurements of critical parameters were made by using the Physical Property Measurement System (PPMS) for 100 mA and 19 Hz in a perpendicular magnetic field. We observed that the Mg coating method can significantly reduce the reactions of B with the Fe sheath. Moreover, the shape, uniformity, and continuity of the layered structure (cracks, gaps) depend on the homogeneity of the B layer before the synthesis reaction. Additionally, the formation of a layered structure depends on the annealing temperature (for Mg in the liquid or solid-state), isostatic pressure, type of boron, and density of layer B before the synthesis reaction.

Revealing the effect of bridges in the multi-filamentary Bi-2212 wires

As the excellent current carrying capacity in ultra-high magnetic fields, Bi-2212(Bi2Sr2CaCu2O8+x ) has attracted much attention. In view of the unique nature of Bi-2212, high-temperature heat treatment is highly needed for the formation of the continuous textured structure in the multi-filamentary Bi-2212 wire. In the meanwhile, bridges between filaments can also be produced in the heat treatment process, which brings structural changes in the wires. However, the mechanism of the effect of the bridges is yet to be understood. In this work, systematical research was carried out on the multi-filamentary Bi-2212 wire for the effect mechanism. Based on the results of the four-probe method and the magnetic moment results, inferiority in Ic combined with a larger magnetic moment at high magnetic fields was detected in samples that have a large number of bridges. Further analysis indicates the inferiority in Ic can be attributed to the reduced cross-sectional area of the filaments and the inferiority in the quality of texture on the basis of results of a series of structural characterizations.

Dynamic test of the continuously variable weak force by a torsion pendulum with pre-applied stress

High-precision, continuously variable weak force testing is required for high-precision drag-free control with micro-thrust of spacecrafts, which is a key technology for space gravitational wave detection programs, such as TianQin, LISA, and Taiji. The continuously variable micro-thrust range is 0.1∼100μN, and the noise is below 0.1 μNHz−1/2 from 10−4Hz to 1 Hz. The torsion pendulum is considered as the most classical weak force measurement tool. However, the large response of non-sensitive modes makes it unsuitable for dynamic weak force measurements. In this study, a dynamic test system is developed for continuously varying weak forces using a torsion pendulum. We pre-applied a stress to the torsion pendulum using a double wire structure, which can effectively reduce the interference of other modes, and used feedback control to improve the stability. The evaluation results obtained using the external continuously variable electrostatic force indicate that the measurement range of the system covers 100 μN, the response time is approximately 1.6 s, and the noise is below 0.1 μNHz−1/2 from 0.9×10−4Hz to 1.4 Hz, which can meet the requirements of the micro-thrust test in space gravitational wave detection missions.