Showing total 73,300 results

151. Preface to Special Topic: Plenary and Invited Papers from the 28th International Conference on the Physics of Semiconductors, Vienna, Austria, 2006

Author

P. James Viccaro

Subjects

Physics, General Physics and Astronomy, Engineering physics

Published

2007

152. On the origin of twist in 3D nucleation islands of tetrahedrally coordinated semiconductors heteroepitaxially grown along hexagonal orientations.

Author

Vennéguès, P., Largeau, L., Brändli, V., Damilano, B., Tavernier, K., Bernard, R., Courville, A., Rennesson, S., Semond, F., Feuillet, G., and Cornet, C.

Subjects

NUCLEATION, SEMICONDUCTORS, ISLANDS, DISLOCATION density, BORON nitride

Abstract

In the first part of this paper, we present a model that explains and determines quantitatively the twists between nucleation islands in the case of a Volmer–Weber heteroepitaxial growth of tetrahedrally coordinated semiconductors along hexagonal orientations. These twists are caused by the network of the screw components of the 60° misfit dislocations. The orientations of the screw components are distributed randomly, and the maximum twist is obtained when all the screw components have the same orientation. The maximum twists are related to the density of misfit dislocations and, therefore, increase with the mismatch between the deposited materials and their substrate. In the second part of the paper, we study five systems having a large distribution of mismatches from 4% to 19%. For the four systems fulfilling the conditions necessary for the application of the model (plastic relaxation of grown islands), the measured maximum twists fit with the calculated values, thereby validating the model. The twists of nucleation islands are related to the mismatch and are, therefore, intrinsic to the material systems. The defects created at the coalescence of twisted islands determine the initial microstructure/defect distribution of the nucleation layer. [ABSTRACT FROM AUTHOR]

Published

2022

153. Computational study of the effect of grain boundary and nano-porosity on xenon behavior in UO2.

Author

Zamzamian, Seyed Mehrdad, Kowsar, Zahra, and Zolfaghari, Ahmadreza

Subjects

CRYSTAL grain boundaries, XENON, WOOD pellets, FISSION products, DIFFUSION coefficients, GRAIN

Abstract

Since xenon (Xe) production is always an unavoidable part of the fission products in fuel pellets, the challenges of its presence have always been the subject of many papers. In line with these goals, in the present paper, the effect of the presence of grain boundaries (GBs) with misorientations (θ G B ) of 36 ° , 39 ° , 52 ° , 53 ° , 71 ° , and 129 ° in 10%Xe-UO2 (uranium dioxide in which 10% of its uranium atoms have been replaced by xenon atoms) on the behavior of xenon (diffusion, nucleation, and formation of clusters) was investigated by performing molecular dynamics (MD) simulations. The results showed that xenon atoms aggregate in the GB with misorientations of 36 ° and 53 ° and form larger clusters relative to other GBs. This was interpreted due to the low formation energy of these two GBs in comparison with other misorientations. A decrease in the number of xenon atoms was also observed at a slight distance from these two GB regions, indicating their sink efficiency. The calculation of diffusion coefficients also indicated that the presence of these two GBs increases the coefficients (xenon, oxygen, and uranium). All of these demonstrate the effective role of θ G B = 36 ° and θ G B = 53 ° in swelling. To reduce the destructive effect of xenon atoms on the fuel pellet, a conceptual design in the form of nanoporous was proposed. The results of the MD simulation of such a design showed that the presence of nano-porosity significantly reduces xenon clusters. [ABSTRACT FROM AUTHOR]

Published

2022

154. Variational algorithm of quantum neural network based on quantum particle swarm.

Author

Dong, Yumin, Xie, Jianshe, Hu, Wanbin, Liu, Cheng, and Luo, Yi

Subjects

PARTICLE swarm optimization, ARTIFICIAL neural networks, QUANTUM superposition, ALGORITHMS

Abstract

Most models of quantum neural networks are optimized based on gradient descent, and like classical neural networks, gradient descent suffers from the barren plateau phenomenon, which reduces the effectiveness of optimization. Therefore, this paper establishes a new QNN model, the optimization process adopts efficient quantum particle swarm optimization, and tentatively adds a quantum activation circuit to our QNN model. Our model will inherit the superposition property of quantum and the random search property of quantum particle swarm. Simulation experiments on some classification data show that the model proposed in this paper has higher classification performance than the gradient descent-based QNN. [ABSTRACT FROM AUTHOR]

Published

2022

155. Surface plasmon resonance enhanced self-powered graphene/Al2O3/InGaAs near-infrared photodetector.

Author

Zhang, Yinglu and Chen, Jun

Subjects

PHOTODETECTORS, SPIN coating, SILVER nanoparticles, INDIUM gallium arsenide, LIGHT absorption, SURFACE plasmons, SURFACE plasmon resonance

Abstract

In recent years, there has been extensive research on improving the performance of photodetectors. In this paper, the performance of a graphene/Al2O3/InGaAs photodetector is studied. In order to reduce the dark current of this device and improve the photocurrent, the structure of the device is optimized to improve the responsivity of the device. A 2 nm thick Al2O3 layer is inserted as the passivation layer. The InP layer between the SiNx layer and the InGaAs layer is retained. It is speculated that the InP layer could reduce the defects and interface states between layers. A layer of silver nanoparticles (Ag NPs) was spin coated on the surface of the single-layer graphene, and the surface plasmon resonance of Ag NPs could enhance the local electric field of InGaAs interface and increase the light absorption of graphene, which can promote carrier generation and transmission in graphene and, thus, effectively enhance the photocurrent of device. The improved device achieves a high responsivity of 265.41 mA/W at 1064 nm and a detection rate of 4.06 × 1011 cm Hz1/2 W−1. At −1.25 V, the responsivity of the device is improved to 1618.8 mA/W. [ABSTRACT FROM AUTHOR]

Published

2022

156. Unified creeping model identifying the critical state of granular materials.

Author

Tong, L. H., Wu, B. N., Lei, Z. X., and Xu, C. J.

Subjects

GRANULAR materials, CRITICAL velocity, MECHANICAL behavior of materials, CREEP (Materials), FRICTION velocity, DEAD loads (Mechanics)

Abstract

The mechanical properties of granular materials at a low shear rate are frequently viewed as rate-independent, and a rate-independent constitutive relation is used to describe the mechanical behaviors of the granular material. However, time-dependent behaviors (or creeping behaviors) become significant in the long run. In this paper, we conduct triaxial experiments to observe the creep of granular materials under both dynamic and static loading conditions. Three typical creeping behaviors, aging, transitional, and fluidic, have been observed. To describe the time-dependent behaviors, an internal state variable characterizing the fluidity of the granular system is introduced to propose a rate-dependent constitutive relation which we call in this paper, a state evolution model. A characteristic strain is also introduced into the model to account for the influences of historic strain on the current state. The experiments are analyzed using the proposed model and it has been found that our model can well discern the observed three creeping behaviors. A criterion to identify the stability of a granular system is also given out based on the proposed model. Two key factors dominating the stability of the granular system are recognized – shear wave velocity and critical velocity. Our laboratory experiments in combination with the proposed criterion offer a physical explanation of the intrinsic triggering mechanism of system evolution from a stable to fluidic state: decrease in wave velocity or/and critical velocity. [ABSTRACT FROM AUTHOR]

Published

2022

157. Comment on "Damage evolution in LiNbO3 due to electronic energy deposition below the threshold for direct amorphous track formation" [J. Appl. Phys. 126, 125105 (2019)].

Author

Szenes, G.

Subjects

POINT defects, AMORPHIZATION, BIOLOGICAL evolution

Abstract

In their article, Wesch et al. deal with defect formation and amorphization in LiNbO3 after irradiation close to the threshold conditions. It is problematic that two thermal spike models are applied in the analysis, which are not compatible with each other. The key parameter of the authors' model—efficiency γ—is derived erroneously in the paper. Formal agreement with the experiments is achieved for point defect production using four parameters for reducing the deviations. It is assumed that amorphization proceeds with the growth of amorphous pockets. However, the conditions of the formation of these pockets are calculated using the inelastic thermal spike model beyond the range of its validity, and this model rejects the basic assumptions of the authors' exciton model. In pursuance of the above criticism, the paper of Wesch et al. is not well thought-out and the experimental results would require a more consequent and closely reasoned analysis. [ABSTRACT FROM AUTHOR]

Published

2020

158. Erratum: "Understanding the response of aluminosilicate and aluminoborate glasses to sharp contact loading using molecular dynamics simulation" [J. Appl. Phys. 128, 035106 (2020)].

Author

Liu, Haidong, Deng, Binghui, Sundararaman, Siddharth, Shi, Yunfeng, and Huang, Liping

Subjects

MOLECULAR dynamics, GLASS, RADIAL distribution function

Abstract

Figures 5-8 show density and Si/Al coordination change during the compression-decompression cycle with and without a shear stress component using the two sets of parameters. In the original paper, the short-range interaction parameters for the Si-Li pair in the SHIK potential[1] were used by mistake for the Si-Na pair in the sodium aluminosilicate (NAS) glass. Si and Al coordination changes during the compression-decompression cycle in NAS without [(a) and (b)] and with shear [(c) and (d)] using the two sets of short-range interaction parameters. [Extracted from the article]

Published

2021

159. Respiratory droplet resuspension near surfaces: Modeling and analysis.

Author

Nikfar, Mehdi, Paul, Ratul, Islam, Khayrul, Razizadeh, Meghdad, Jagota, Anand, and Liu, Yaling

Subjects

SURFACE analysis, CONTACT angle, HYDROPHOBIC surfaces, SURFACE energy, MEDICAL personnel, SURGICAL gloves

Abstract

Knowing the environmental spreading pathway of COVID-19 is crucial for improving safety practices, particularly for health care workers who are more susceptible to exposure. This paper focuses on the possible secondary transmission due to resuspension of virus-laden droplets from common surfaces, which several studies have shown to be possible under external disturbances. Such disturbances could be body motion during walking, running, clothes removal, or airflow in the environment. In this paper, a three-dimensional two-phase model is utilized to study respiratory droplet resuspension dynamics on various surfaces due to sudden agitation. The velocity range and variation during walking, surgical glove removal, and dropping an object are studied experimentally. A parametric study is performed to characterize the effects of droplet size and surface wettability on the minimum initial droplet velocity required for detachment from surfaces. The results are reported as average droplet velocity during the detachment process, total detachment time, and detached droplet volume. The obtained results indicate that respiratory droplets larger than 200 μm can detach from typical surfaces due to normal daily activities. Droplets are partially separated from hydrophilic surfaces with contact angle ≤ 90 ° , while the entire droplet is detached from hydrophobic surfaces with contact angle > --> 90 °. Furthermore, the minimum initial droplet velocity to induce the resuspension depends on the droplet size. Droplet velocity immediately after detachment is a function of droplet size, initial droplet velocity, and surface wettability. Bigger droplets have larger detached volume percentage as well as higher velocity after detachment compared to smaller droplets. Finally, a higher initial velocity is needed to separate droplets from hydrophilic surfaces as compared to hydrophobic surfaces. In accordance with the results, the droplet minimum initial velocity to cause detachment is 2 m s−1, while our experiments show that surface velocity can reach up to 3 m s−1 during normal human activities. We also develop an analytical model to predict the required kinetic energy to detach droplets from different surfaces, which is in good agreement with numerical results. The mechanism of droplet detachment is dictated by a competition between droplet kinetic energy induced by surface motion and surface energy due to droplet–surface interaction as well as droplet–vapor and surface–vapor interactions. We believe that the results of this fundamental study can potentially be used to suggest proper surface wettability and safe motion that reduce respiratory droplet resuspension from various surfaces. [ABSTRACT FROM AUTHOR]

Published

2021

160. Evanescent surface acoustic waves in 1D viscoelastic phononic crystals.

Author

Zhang, Shu-Yan, Wang, Yan-Feng, and Wang, Yue-Sheng

Subjects

ACOUSTIC surface waves, PHONONIC crystals, FINITE element method, SOUND waves, CRYSTAL surfaces

Abstract

In this paper, evanescent surface waves propagating in a one-dimensional surface phononic crystal are investigated. The phononic crystal consists of elastic pillars periodically arranged on a viscoelastic substrate. By using the finite element method, the complex band structures and transmission spectra of surface waves are calculated. It is found that the evanescent wave with π phase change of the real part lies inside the resonant bandgap, and no cusp is observed for the minimum imaginary part. With the increase of frequency, the surface waves can be gradually converted to bulk waves. When the pillar height is increased, the generation mechanism of the first bandgap gradually varies from Bragg scattering to local resonance, and the evanescent waves above the sound line can be reconstructed and shifted below the sound line. When the viscosity is introduced, the minimum imaginary part inside the bandgap decreases. However, the corresponding attenuation is strengthened because the contribution of the bulk wave to the transmission gets weak. The work in this paper is relevant to the practical application of surface waves. [ABSTRACT FROM AUTHOR]

Published

2021

161. A Method for Studying the Distribution and Sign of Static Charges on Solid Materials.

Author

Hull, Harry H.

Published

1949

162. Ab initio calculations of structural stability, thermodynamic and elastic properties of Ni, Pd, Rh, and Ir at high pressures.

Author

Smirnov, N. A.

Subjects

THERMODYNAMICS, AB-initio calculations, ELASTICITY, STRUCTURAL stability, BODY centered cubic structure

Abstract

This paper presents results of a comprehensive study from first principles into the properties of Ni, Pd, Rh, and Ir crystals under pressure. We calculated elastic constants, phonon spectra, isotherms, Hugoniots, sound velocities, relative structural stability, and phase diagrams. It is shown that in nickel and palladium under high pressures (>0.14 TPa) and temperatures (>4 kK), the body-centered cubic structure is thermodynamically most stable than of the face-centered cubic one. Calculated results suggest that nickel under Earth-core conditions (P ∼ 0.3 TPa, T ∼ 6 kK) have a bcc structure. No structural changes were found to occur in Rh and Ir under pressures to 1 TPa at least. This paper also provides estimations for the pressure and temperature at which the metals of interest begin to melt under shock compression. [ABSTRACT FROM AUTHOR]

Published

2023

163. Construct Schottky interface containing energy-filtering effect: An efficient strategy to decouple thermopower and conductivity.

Author

Lin, Zizhen, Ping, Xiaofan, Zhao, Dongming, Wang, Lichuang, Li, Menglei, Cai, Zihe, Zhang, Yun, Li, Xinlian, and Zhang, Xuankai

Subjects

THERMOELECTRIC power, THERMOELECTRIC materials, IMPURITY centers, ELECTRIC conductivity, CHARGE carriers, SEEBECK coefficient, FILTERS & filtration

Abstract

Organic/inorganic thermoelectric hybrids demonstrate great potential for wearable applications. However, their scalability is hindered by an inferior power factor (S 2 σ). Nowadays, achieving deep optimization of S 2 σ necessitates a strategy to decouple the Seebeck coefficient (S) and electrical conductivity (σ). In this work, we propose a strategy to break the coupling between S and σ by constructing a Schottky interface that exhibits an energy-filtering effect. We validate the feasibility of this approach using a PANI/TiN–TiO2/carbon paper. The results demonstrate a 1.16-fold increase in σ and a 1.08-fold increase in S in PANI/TiN–TiO2/carbon paper achieved through the construction of a Schottky-type TiN/TiO2 interface. The separation of hole/electron at the TiN/TiO2 interface serves as the scattering center for ionized impurity scattering and facilitates the transport pathway for charge carriers. These factors are crucial in determining the simultaneous optimization of S and σ , respectively. Additionally, the energy-filtering effect of the TiN/TiO2 interface plays a positive role in the ionized impurity scattering mechanism by selectively filtering out low-energy carriers. This further strengthens decoupling of the thermoelectric properties. The 14.9% PANI/11.2% TiN–14.5% TiO2/59.44% carbon paper displays the highest S 2 σ and achieves a high ZT value of 223.6 μVm−1 K−2 and 0.31 at 300 K, highlighting the advantages of PANI-based thermoelectric hybrids. This work provides valuable guidance for the design of thermoelectric hybrids incorporating multi-interface morphology. [ABSTRACT FROM AUTHOR]

Published

2023

164. Time-domain minimum-volume cell photoacoustic of thin semiconductor layer. I. Theory.

Author

Galovic, S. P., Djordjevic, K. Lj., Nesic, M. V., Popovic, M. N., Markushev, D. D., Markushev, D. K., and Todorovic, D. M.

Subjects

SEMICONDUCTORS, HEAT conduction, CELL size, INVERSE problems, PROBLEM solving

Abstract

The model of a photoacoustic gas-microphone signal in the time domain recorded in a transmission configuration using a minimum volume cell is derived. This model takes into account the inertial thermal relaxations of both the sample and the gas filling the cell by means of the generalized hyperbolic theory of heat conduction. With the introduction of electro-thermal analogy for the thin sample and short microphone length cavity, characteristic quantities are defined, which can be used in solving the inverse problem in time-domain photoacoustic in both cases, when thermal relaxations are neglected as well as when they are considered. The derived model that includes thermal relaxation explains the experimentally observed occurrence of overshoots and undershoots as well as an oscillatory approach to the steady values of the recorded signal in high-resolution time-domain photoacoustic measurements of thin semiconductor membranes, which will be presented in detail in Paper II of the paper. [ABSTRACT FROM AUTHOR]

Published

2023

165. The effect of stress on HfO2-based ferroelectric thin films: A review of recent advances.

Author

Han, Runhao, Hong, Peizhen, Ning, Shuai, Xu, Qiang, Bai, Mingkai, Zhou, Jing, Li, Kaiyi, Liu, Fei, Shi, Feng, Luo, Feng, and Huo, Zongliang

Subjects

FERROELECTRIC thin films, FERROELECTRIC devices, THIN films, MANUFACTURING processes, COMPLEMENTARY metal oxide semiconductors

Abstract

HfO 2 -based thin films have raised considerable interest in ferroelectric memory devices due to their thickness scalability and process compatibility with CMOS. Stress exhibits a significant influence on ferroelectric polarization in HfO 2 -based films. However, the effect of stress has yet to be clarified despite numerous efforts, and there has been a lack of systematic review to collate and discuss this effect. This paper briefly introduces how stress is characterized in HfO 2 -based polycrystalline films as basis. Then, the process in which stress affects ferroelectricity is carefully discussed. The paper subsequently elaborates both the effects of out of plane stress and in plane stress. Furthermore, the interaction between stress and other factors is presented. Finally, the up-to-date research on the effect of stress are summarized, and several further research challenges for researchers are provided. Given the ubiquitous stress during the chip manufacturing process, a detailed summary of the stress effect has technological implications for processing and applications of HfO 2 -based thin films. [ABSTRACT FROM AUTHOR]

Published

2023

166. Quantum computing and materials science: A practical guide to applying quantum annealing to the configurational analysis of materials.

Author

Camino, B., Buckeridge, J., Warburton, P. A., Kendon, V., and Woodley, S. M.

Subjects

QUANTUM annealing, MATERIALS science, QUANTUM computing, MATERIALS analysis, QUANTUM computers, COMPUTATIONAL chemistry

Abstract

Using quantum computers for computational chemistry and materials science will enable us to tackle problems that are intractable on classical computers. In this paper, we show how the relative energy of defective graphene structures can be calculated by using a quantum annealer. This simple system is used to guide the reader through the steps needed to translate a chemical structure (a set of atoms) and energy model to a representation that can be implemented on quantum annealers (a set of qubits). We discuss in detail how different energy contributions can be included in the model and what their effect is on the final result. The code used to run the simulation on D-Wave quantum annealers is made available as a Jupyter Notebook. This Tutorial was designed to be a quick-start guide for the computational chemists interested in running their first quantum annealing simulations. The methodology outlined in this paper represents the foundation for simulating more complex systems, such as solid solutions and disordered systems. [ABSTRACT FROM AUTHOR]

Published

2023

167. Effective properties of graded radially polarized piezoelectric cylindrical composites.

Author

Wei, Jia-Qi, Wu, Da-Wei, and Kaswango, Leon

Subjects

PIEZOELECTRIC composites, SEPARATION of variables, ELASTICITY

Abstract

This paper presents a theoretical study of a graded piezoelectric composite consisting of an infinitely long graded radially polarized piezoelectric cylinder embedded in an isotropic elastic non-piezoelectric matrix, under an external strain field. The physical properties of the graded cylindrical inclusion have a power-law profile with respect to the cylindrical radial variable. Using the variable separation method, closed-form solutions for the elastic displacement and electrical field in the entire composite regions are derived from the governing equation. The effective elastic and piezoelectric properties of the graded piezoelectric composite are formulated and discussed. The study reveals a vanishing mechanism of effective piezoelectric response in the graded radially polarized cylindrical piezoelectric composite. In addition, the paper derives the effective elastic formulas of the graded cylindrical elastic composites for the purely elastic problem and discusses the effects of graded property parameters on the effective elastic properties. [ABSTRACT FROM AUTHOR]

Published

2023

168. Segmentation and accurate identification of large carious lesions on high quality x-ray images based on Attentional U-Net model. A proof of concept study.

Author

Li, Wei, Zhu, Xueyan, Wang, Xiaochun, Wang, Fei, Liu, Junyan, Chen, Mingjun, Wang, Yang, and Yue, Honghao

Subjects

DEEP learning, X-ray imaging, DENTAL caries, PROOF of concept, IMAGE segmentation, IMAGE recognition (Computer vision), X-rays

Abstract

Dental caries is a bacterial infectious disease that destroys the structure of teeth. It is one of the main diseases that endanger human health [R. H. Selwitz, A. I. Ismail, and N. B. Pitts, Lancet 369(9555), 51–59 (2007)]. At present, dentists use both visual exams and radiographs for the detection of caries. Affected by the patient's dental health and the degree of caries demineralization, it is sometimes difficult to accurately identify some dental caries in x-ray images with the naked eye. Therefore, dentists need an intelligent and accurate dental caries recognition system to assist diagnosis, reduce the influence of doctors' subjective factors, and improve the efficiency of dental caries diagnosis. Therefore, this paper combines the U-Net model verified in the field of biomedical image segmentation with the convolution block attention module, designs an Attention U-Net model for caries image segmentation, and discusses the feasibility of deep learning technology in caries image recognition so as to prepare for the next clinical verification. After testing, the Dice similarity coefficient, mean pixel accuracy, mean intersection over union, and frequency-weighted intersection over the union of teeth segmentation with Attention U-Net are 95.30%, 94.46%, 93.10%, and 93.54%, respectively. The Dice similarity coefficient, mean pixel accuracy, mean intersection over union, and frequency-weighted intersection over the union of dental caries segmentation with Attention U-Net are 85.36%, 91.84%, 82.22%, and 97.08%, respectively. As a proof of concept study, this study was an initial evaluation of technology to assist dentists in the detection of caries. There is still more work needed before this can be used clinically. [ABSTRACT FROM AUTHOR]

Published

2022

169. Understanding the factors affecting contact resistance in nanowire field effect transistors (NWFETs) to improve nanoscale contacts for future scaling.

Author

Ramesh, S., Ivanov, Ts., Sibaja-Hernandez, A., Alian, A., Camerotto, E., Milenin, A., Pinna, N., El Kazzi, S., Lin, D., Lagrain, P., Favia, P., Bender, H., Collaert, N., and De Meyer, K.

Subjects

FIELD-effect transistors, NANOWIRES, PLASMA etching, SURFACE states, LOW temperatures, OHMIC contacts

Abstract

In this paper, dry etched vertical nanowires (VNWs) are used in transmission line/transfer length analysis to study the contacts of gate-all-around devices for future technology nodes. VNW resistors with Mo and Pd based metal stack contacts to p-InGaAs show Schottky behavior, unlike the planar counterpart. The resistance for Mo contact is higher than Pd, however, Pd was found to form an alloy with InGaAs at temperatures as low as 190 °C, and the length of Pd diffusion into the InGaAs increased at smaller NW dimensions, hindering future scalability. The minimum extracted specific contact resistivity (ρC) values are 1.6 × 10−5 Ω cm2 (Mo) and 4.2 × 10−6 Ω cm2 (Pd) for a doping level of 1 × 1019 cm−3. An apparent dependence of ρC on the NW diameter was also observed. This has been attributed to the surface states under the un-gated region of NW devices and found to dominate at smaller diameters. An analytical model to account for such geometrical effects has also been developed and validated with technology computer-aided design simulations. The analysis presented in this paper effectively captures the 3D aspects of an NW contact at nanoscale dimensions and can be applied irrespective of the semiconductor and contact metal used. [ABSTRACT FROM AUTHOR]

Published

2022

170. Piezoelectric acoustic wave characteristics of Pb(In0.5Nb0.5)O3-Pb(Mg1/3Nb2/3)O3-PbTiO3 single crystal substrate: A comparative study with and without SiO2 overlay.

Author

Zhang, Qiaozhen, Du, Rufan, Li, Baichuan, Liu, Huiling, Zhao, Xiangyong, Chen, Ziyun, and Luo, Haosu

Subjects

SOUND waves, ACOUSTIC surface waves, SINGLE crystals, QUALITY factor, TRANSDUCERS, FERROELECTRIC crystals, ELECTROMECHANICAL effects, LEAD titanate

Abstract

This paper investigates the excitation and propagation characteristics of a piezoelectric acoustic wave propagating in a rotated Y-cut X-propagating Pb(In0.5Nb0.5)O3-Pb(Mg1/3Nb2/3)O3-PbTiO3 (PIN-PMN-PT) relaxor-based ferroelectric single crystal substrate. Numerical simulations were performed to evaluate the acoustic wave properties by FEM software COMSOL. For comparison, two types of structures are taken into consideration: one is the traditional metal electrode/YX-PIN-PMN-PT and the other is silicon dioxide (SiO2) overlay/metal electrode/YX-PIN-PMN-PT substrate. It is shown that shear-horizontal (SH)-type piezoelectric boundary acoustic waves (PBAW) exist in the SiO2 overlay/metal electrode/YX-PIN-PMN-PT substrate and offer a fairly large electromechanical coupling factor K2 of 30%. Compared to a surface acoustic wave excited in the metal electrode/YX-PIN-PMN-PT substrate, enlarged phase velocity and significantly improved quality factor (∼3500) are simultaneously obtained for SH-type PBAW, which are promising for electromechanical transducer applications with high performance. [ABSTRACT FROM AUTHOR]

Published

2022

171. Substrate-supported nano-objects with high vibrational quality factors.

Author

Crut, Aurélien

Subjects

ACOUSTIC emission, QUASI bound states, QUALITY factor, SOUND waves, ACOUSTIC vibrations, SYMMETRY breaking

Abstract

Recent optical time-resolved experiments on single supported nano-objects (gold nanodisks with various diameter over thickness ratios) have demonstrated a marked enhancement of their vibrational quality factors for specific nano-object morphologies, resulting from the near-suppression of radiative vibrational damping associated with the emission of acoustic waves in the nano-object environment. This paper clarifies the origin of this phenomenon, which is ascribed to the creation of a "quasi-bound state in the continuum" vibrational mode by radiative coupling between two nano-object modes whose frequencies become close for specific nano-object shapes. The symmetry breaking induced by the presence of a substrate, which limits nanodisk acoustic emission to a half-space, is shown to play an essential role in enabling such radiative coupling. The impact of the acoustic mismatch between the nano-object and the substrate is explored, and it is shown that a moderate acoustic mismatch can still enable the creation of near-localized vibrational modes with high radiative quality factors, while allowing radiative coupling effects to occur over a broad range of nano-object geometries. Although this paper focuses on the situation of a substrate-supported gold nanodisk, which has already been the object of experimental investigations, the effects that it describes are general and constitute a promising approach to enhance the vibrational quality factors of nano-objects. [ABSTRACT FROM AUTHOR]

Published

2022

172. Estimation of the convolutional neural network with attention mechanism and transfer learning on wood knot defect classification.

Author

Gao, Mingyu, Wang, Fei, Liu, Junyan, Song, Peng, Chen, Jianfeng, Yang, Hong, Mu, Hongbo, Qi, Dawei, Chen, Mingjun, Wang, Yang, and Yue, Honghao

Subjects

CONVOLUTIONAL neural networks, WOOD, ARTIFICIAL neural networks, MANUFACTURING processes, NONDESTRUCTIVE testing

Abstract

In the intelligent production process of wood products, the classification system of wood knot defects is a very practical solution. However, traditional image processing methods cannot handle it well due to the uncertainty of manually extracted features. Therefore, a lightweight and reliable artificial neural network model is proposed to classify and identify our objective. To solve this problem, a wood knot defect recognition model named SE-ResNet18 combining convolutional neural network, attention mechanism, and transfer learning is proposed in this paper. First, the Sequence-and-Exception (SE) module is combined with Basicblock and is constructed as two modules called RBBSE-1 and RBBSE-2. These modules learn to enhance features that are useful for the current task, suppress useless features, and fuse the output features with the original features. Then, the fully connected layer is replaced with a global average pooling layer, which can effectively reduce the parameters of the fully connected layer in the model. Finally, a SE-ResNet18 was constructed by one convolutional layer, five RBBSE-1 modules, and three RBBSE-2 modules of different channels. The SE-ResNet18 has a higher accuracy (98.85%) in the test set compared to the unimproved model ResNet-18. Compared with the previously proposed ReSENet-18, more SE modules are used in SE-ResNet18 to provide a basis for future training on a larger-scale dataset. Based on the same test set, a comparison with other classical models (such as LeNet-5, AlexNet, etc.) was conducted, and the results validated the superiority of the proposed model. The proposed model achieves the expected objective and provides a new way of thinking for non-destructive testing of wood. [ABSTRACT FROM AUTHOR]

Published

2022

173. Electronic and magnetic properties of vanadium dichalcogenides: A brief overview on theory and experiment.

Author

Abdul Wasey, A. H. M. and Das, G. P.

Subjects

MAGNETIC properties, ANOMALOUS Hall effect, CHARGE density waves, QUANTUM confinement effects, TRANSITION metals, VANADIUM, TRANSITION metal oxides

Abstract

Two-dimensional layered materials, in general, and transition metal dichalcogenides, in particular, are promising as future device materials. Vanadium based dichalcogenides, i.e., VX2 (X = S, Se, and Te) are special in the class for showing a wide range of intriguing properties. Depending on the structural phases, VX2 can be metallic or semiconducting. The T-phase, i.e., the metallic one, is well known to host some exotic electronic properties like the charge density wave, anomalous Hall effect, ferromagnetism, etc., having strong bearing as an electronic device material. The H-phase, on the other hand, is also predicted to show ferromagnetism. The materials show properties strongly dependent on their physical dimensionality, a clear manifestation of quantum confinement effects. Several experimental attempts successfully demonstrated chemical and bio-medical applications also of this class of materials. Moreover, the heterostructures formed by VX2 with other electronically dissimilar materials could bring more variation in their existing properties. Therefore, the study of VX2 materials provides a fertile ground to explore several fascinating physical phenomena and their possibilities in future applications. Here, in the present paper, we have tried to review the current scenario in this particular field by highlighting some recent key findings. The paper is aimed at providing some insight into the recent theoretical and experimental achievements in this direction, especially in the context of electronic and magnetic properties in their lower physical dimensionality. This could furnish a comprehensive guiding tour toward exploration in the journey through VX2 materials. [ABSTRACT FROM AUTHOR]

Published

2022

174. Measurement of Charge Transfer in Electrographic Processes.

Author

Brodie, I., Dahlquist, J. A., and Sher, A.

Published

1968

175. Domain walls in bubble films. II. Static properties of thick films.

Author

Schlömann, Ernst

Published

1973

176. Particle behavior simulation in thermophoresis phenomena by direct simulation Monte Carlo method.

Author

Takao Wada

Subjects

THERMOPHORESIS, COLLISIONS (Nuclear physics), MONTE Carlo method, NUCLEAR reactors, GREEN'S functions

Abstract

A particle motion considering thermophoretic force is simulated by using direct simulation Monte Carlo (DSMC) method. Thermophoresis phenomena, which occur for a particle size of 1 μm, are treated in this paper. The problem of thermophoresis simulation is computation time which is proportional to the collision frequency. Note that the time step interval becomes much small for the simulation considering the motion of large size particle. Thermophoretic forces calculated by DSMC method were reported, but the particle motion was not computed because of the small time step interval. In this paper, the molecule-particle collision model, which computes the collision between a particle and multi molecules in a collision event, is considered. The momentum transfer to the particle is computed with a collision weight factor, where the collision weight factor means the number of molecules colliding with a particle in a collision event. The large time step interval is adopted by considering the collision weight factor. Furthermore, the large time step interval is about million times longer than the conventional time step interval of the DSMC method when a particle size is 1 μm. Therefore, the computation time becomes about one-millionth. We simulate the graphite particle motion considering thermophoretic force by DSMC-Neutrals (Particle-PLUS neutral module) with above the collision weight factor, where DSMC-Neutrals is commercial software adopting DSMC method. The size and the shape of the particle are 1 μm and a sphere, respectively. The particle-particle collision is ignored. We compute the thermophoretic forces in Ar and H2 gases of a pressure range from 0.1 to 100 mTorr. The results agree well with Gallis' analytical results. Note that Gallis' analytical result for continuum limit is the same as Waldmann's result. [ABSTRACT FROM AUTHOR]

Published

2014

177. Dimensional variation of reconfigurable serpentine graphene nanoribbon under tension.

Author

Wang, Yafei, Wang, Changguo, Zhang, Yunce, Guo, Jiaming, and Tan, Huifeng

Subjects

GRAPHENE, NANORIBBONS, SERPENTINE, MAGNETIC control, TOPOLOGY

Abstract

In this paper, we resort to single-layer graphene nanoribbon (GN) and atomistic simulation to explore the dimensional variation of serpentine graphene. A tensile model of serpentine GN is established, and its topology responses are investigated with some counterintuitive expectations. A laser scanning experiment on the serpentine sheet of paper is performed and compared, which can indirectly reflect the reduced-dimensionality tendency of serpentine GN in tension. As a result, serpentine GN provides a dynamic route of transforming lateral and longitudinal dimensions. Our obtained results can be used to the thermal, electric, or magnetic controlling in future applications. [ABSTRACT FROM AUTHOR]

Published

2019

178. Flexible hybrid circuit fully inkjet-printed: Surface mount devices assembled by silver nanoparticles-based inkjet ink.

Author

Arrese, J., Vescio, G., Xuriguera, E., Medina-Rodriguez, B., Cornet, A., and Cirera, A.

Subjects

INK-jet printers, SURFACE mount technology, SILVER nanoparticles, HYBRID integrated circuits, CONTACT resistance (Materials science)

Abstract

Nowadays, inkjet-printed devices such as transistors are still unstable in air and have poor performances. Moreover, the present electronics applications require a high degree of reliability and quality of their properties. In order to accomplish these application requirements, hybrid electronics is fulfilled by combining the advantages of the printing technologies with the surface-mount technology. In this work, silver nanoparticle-based inkjet ink (AgNP ink) is used as a novel approach to connect surface-mount devices (SMDs) onto inkjet-printed pads, conducted by inkjet printing technology. Excellent quality AgNP ink-junctions are ensured with high resolution picoliter drop jetting at low temperature (~150 °C). Electrical, mechanical, and morphological characterizations are carried out to assess the performance of the AgNP ink junction. Moreover, AgNP ink is compared with common benchmark materials (i.e., silver epoxy and solder). Electrical contact resistance characterization shows a similar performance between the AgNP ink and the usual ones. Mechanical characterization shows comparable shear strength for AgNP ink and silver epoxy, and both present higher adhesion than solder. Morphological inspections by field-emission scanning electron microscopy confirm a high quality interface of the silver nanoparticle interconnection. Finally, a flexible hybrid circuit on paper controlled by an Arduino board is manufactured, demonstrating the viability and scalability of the AgNP ink assembling technique. [ABSTRACT FROM AUTHOR]

Published

2017

179. Photoacoustic study of layer thickness and moisture content from varnished packaging materials.

Author

Walther, H. G. and Christ, A.

Subjects

*PAPER coatings, *PAPER containers, *PACKAGING equipment, *MATERIALS analysis

Abstract

By means of a photoacoustic gas-cell technique we estimated the thickness of varnish layers on base paper. Interpretation of the measurements was supported by a theoretical model which describes the packaging material as a multilayer stack with freely eligible thermal and optical properties. The variable moisture content could be taken into account using mixture formulas for the definition of thermal effusivity and thermal diffusivity at different percentages of water. Satisfying correspondence between photoacoustic phase slope measurements and calculations simulating water migration was able to be achieved. © 2001 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2001

180. Preface to Special Topic: Invited Papers of the 58th Annual Conference on Magnetism and Magnetic Materials, Denver, Colorado, USA, November 2013.

Author

Hoffmann, Axel

Subjects

MAGNETISM

Abstract

A preface to the June 6, 2014 issue of the "Journal of Applied Physics," with papers on the 58th Annual Conference on Magnetism and Magnetic Materials is presented.

Published

2014

181. Symmetry-breaking instability in a charge-controlled dielectric film: Large electro-actuation and high stored energy.

Author

Chen, Lingling, Xing, Xinyu, and Yang, Shengyou

Abstract

In this paper, we study the electromechanical behaviors of a charge-controlled dielectric film that may encounter symmetry-breaking instability. With electric charges and the radial dead load, a circular film would gradually expand its area and become a large circular film; however, it will deform into an elliptical film when electromechanical loads increase to the threshold. This symmetry-breaking instability brings the change of shape and makes the dielectric film achieve large electro-actuation and high stored energy. Since the functionality of the dielectric devices is also limited by the electric breakdown, we give the phase diagram to show the competition between the symmetry-breaking instability and the electric breakdown in detail. This paper is desirable to further harness the symmetry-breaking instability for improving functionalities of actuators and harvesters. [ABSTRACT FROM AUTHOR]

Published

2022

182. Design considerations for gallium arsenide pulse compression photoconductive switch.

Author

Dong, Yicong, Dowling, Karen M., Hau-Riege, Stefan P., Conway, Adam, Voss, Lars F., and Rakheja, Shaloo

Subjects

GALLIUM arsenide, SPACE charge, GENERATING functions, AUDITING standards, LASERS

Abstract

In this paper, we present the physics and design-space exploration of a novel pulse compression photoconductive switch (PCPS) using semi-insulating gallium arsenide (GaAs) operating in the negative differential mobility (NDM) regime of electron transport. We systematically quantify the relationship between the PCPS performance and various design options, including contact separation, laser energy and placement, and trap dynamics. Specifically, we report the full-width at half-maximum and the peak output current generated by the PCPS as a function of applied electrical and optical bias. We discuss the optimal spacing between the electrodes and the distance of the laser spot to the anode to achieve higher electron confinement and superior radio-frequency (RF) metrics. Reducing the laser energy is important to prevent the appearance of secondary peaks due to diffusive transport, but there exists a trade-off between the bandwidth and the maximum current of the PCPS. We also compare the PCPS response with and without trap dynamics and find that the electrostatic screening from the trap-induced space charge is time-independent when the trapping time constant is set larger than the recombination lifetime. Overall, trap dynamics are detrimental to performance, unless the compensation doping scheme to achieve semi-insulating GaAs is carefully selected. Results presented in this paper can be used by experimentalists to fine-tune the PCPS design parameters to meet the specifications of various RF applications. Moreover, our results will provide a strong theoretical basis to the measurements of PCPS devices using GaAs and other NDM materials under investigation. [ABSTRACT FROM AUTHOR]

Published

2022

183. Carbonaceous sulfur hydride system: The strong-coupled room-temperature superconductor with a low value of Ginzburg–Landau parameter.

Author

Wrona, I. A., Kostrzewa, M., Krok, K. A., Durajski, A. P., and Szczȩśniak, R.

Subjects

HYDROGEN sulfide, SUPERCONDUCTORS, HYDRIDES, COUPLING constants, MAGNETIC transitions, CRITICAL temperature

Abstract

The superconducting state in a carbonaceous sulfur hydride (C–S–H) system is probably characterized by the record-high critical temperature of 288 K (p ≈ 267 GPa). We determined the properties of the C–S–H superconducting phase within the scope of both classical Eliashberg equations and the Eliashberg equations with vertex corrections. We took into account the scenarios pertinent to either the intermediate or the high value of an electron–phonon coupling constant (λ ≈ 0.75 or λ ≈ 3.3 , respectively). The scenario for the intermediate value, however, cannot be actually realized due to the anomalously high value of the logarithmic phonon frequency (ω ln / k B = 7150 K) it would require. On the other hand, we found it possible to reproduce correctly the value of T C and other thermodynamic quantities in the case of strong coupling, with all the reservations discussed in the presented paper. The vertex corrections lower the order parameter values within the range from ≈ 50 K to ≈ 275 K. For the upper critical field H C 2 ≈ 27 T, the Ginzburg–Landau parameter κ is of the order of 1.7. The strong-coupling scenario for the C–S–H system is also suggested by the high values of λ estimated for H 3 S (λ ≈ 2.1 , κ ≈ 1.5), La H 10 (λ ≈ 2.8 – 3.9 , κ ≈ 1.6), and Y H 6 (λ ≈ 1.7 , κ ≈ 1.3) compounds. In the case of the C–S–H system, we also anticipate the presence of the antiferromagnetic state above the superconducting state like in the dense C S 2 superconductor. For p ≈ 174 GPa and T C ≈ 180 K, the magnetic ordering transition occurs at T N ≈ 213 K. [ABSTRACT FROM AUTHOR]

Published

2022

184. Dynamics of the transition resistance of Al–(Ti, Ni, Mo)–Si type contacts under conditions of non-stationary electrical loads.

Author

Skvortsov, Arkadiy A., Koryachko, Marina V., Kuleshova, Svetlana I., and Rybakova, Margarita R.

Subjects

ELECTRICAL load, ELECTRIC currents, OHMIC contacts, QUALITY control, SEMICONDUCTORS

Abstract

This paper analyses the behavioral features of ohmic contacts under the conditions of traditional isothermal annealing. The purpose of this paper is to study the value change of the semiconductor contact resistance when applying electric current pulses of different powers. For the experiments, structures were formed of metal-sublayer-semiconductor wafer Al–(Ti, Ni, Mo)–Si. The quality control of the deposited films was carried out microscopically by the four-probe method. The presented results indicate the solid-phase interaction of components during diffusion annealing Si–Me–Al thin-film systems. This rearrangement of atoms, which occurs with grain-boundary diffusion, significantly affects the electrical and thermal characteristics of the formed contacts. The novelty of the paper is that the optimal parameters of a rectangular current pulse were selected, which made it possible to reduce the value of the transition resistance by 1.6 times. [ABSTRACT FROM AUTHOR]

Published

2022

185. Non-homogeneous cross section variation enhanced flexoelectric coupling in semiconductor beams and its application in charge carrier redistribution.

Author

Zhao, Luke, Li, Peng, and Jin, Feng

Subjects

CHARGE carriers, CARRIER density, FLEXOELECTRICITY, ELECTRIC charge, SEMICONDUCTORS, ELECTRIC potential, SEMICONDUCTOR devices

Abstract

A pure bending semiconductor beam that exhibits a non-homogeneous cross section variation enhanced flexoelectric coupling effect is investigated in this paper from the point of view of theoretical analysis and numerical calculations. According to the macroscopic theory of flexoelectric semiconductors, a one-dimensional bending model for a simple-supported beam with variable cross section is developed. The semi-analytical method, which is composed of cosine series and supplementary functions, is introduced to solve the partial differential equations with variable coefficients. Before the analysis, the convergence and correctness of the semi-analytical method are demonstrated systematically. The calculated results show that both the electric potential and the charge carrier distribute non-homogeneously in the entire beam under a pair of symmetric bending moments. It is revealed that more carriers, a larger electric potential, and more charges tend to concentrate in the zone near the ends. After introducing a dimensionless carrier density, this paper systematically investigates the non-homogeneous cross section variation effect on the flexoelectric coupling for charge carrier redistribution. It is indicated that more perturbation carriers in a non-uniform beam are produced by the enhanced flexoelectric coupling. The demonstration of this concept could be potential guidance for designing new semiconductor devices. [ABSTRACT FROM AUTHOR]

Published

2022

186. Electromechanical behaviors in piezotronic quantum wells based on a quantum-corrected phenomenological theory.

Author

Li, Nian, Fang, Kai, Li, Peng, Chen, Feng, Qian, Zhenghua, Kolesov, Vladimir, and Kuznetsova, Iren

Subjects

ELECTRIC potential, ELECTRON density, PIEZOELECTRICITY, ELECTROMECHANICAL effects, MOLE fraction, QUANTUM wells, SEMICONDUCTORS, ENGINEERING

Abstract

Piezotronic devices have attracted a great deal of attention due to their potential applications in self-powered tactile sensing, nano-device memory, human-electronic interface, etc. As the size of piezotronic devices shrinks, some interesting quantum effects begin to appear. In this paper, we establish a theory oriented to the engineering application of piezoelectric semiconductors, called quantum-corrected phenomenological (QCP) theory, by coupling the density-gradient theory and the linear piezoelectricity theory through Gauss's law. For numerical verification, we specifically studied the electromechanical behaviors in GaN/AlGaN heterostructure quantum wells (QWs) with both infinite and finite barrier height. The results of electron density, electric potential, and quantum potential are provided, and their dependence on the doping density, the applied stress, and the Al mole fraction is investigated. Some interesting quantum effects are revealed, and their influencing mechanisms are well investigated from a macroscopic perspective. Not only do the conclusions drawn in this paper enrich the fundamental understanding of the piezotronic effect in a QW structure, but also the proposed QCP theory can serve as a valuable tool for future device engineering. [ABSTRACT FROM AUTHOR]

Published

2022

187. Unraveling the impact of initial choices and in-loop interventions on learning dynamics in autonomous scanning probe microscopy.

Author

Slautin, Boris N., Liu, Yongtao, Funakubo, Hiroshi, and Kalinin, Sergei V.

Abstract

The current focus in Autonomous Experimentation (AE) is on developing robust workflows to conduct the AE effectively. This entails the need for well-defined approaches to guide the AE process, including strategies for hyperparameter tuning and high-level human interventions within the workflow loop. This paper presents a comprehensive analysis of the influence of initial experimental conditions and in-loop interventions on the learning dynamics of Deep Kernel Learning (DKL) within the realm of AE in scanning probe microscopy. We explore the concept of the "seed effect," where the initial experiment setup has a substantial impact on the subsequent learning trajectory. Additionally, we introduce an approach of the seed point interventions in AE allowing the operator to influence the exploration process. Using a dataset from Piezoresponse Force Microscopy on PbTiO3 thin films, we illustrate the impact of the "seed effect" and in-loop seed interventions on the effectiveness of DKL in predicting material properties. The study highlights the importance of initial choices and adaptive interventions in optimizing learning rates and enhancing the efficiency of automated material characterization. This work offers valuable insights into designing more robust and effective AE workflows in microscopy with potential applications across various characterization techniques. [ABSTRACT FROM AUTHOR]

Published

2024

188. AlGaN/GaN bilateral IMPATT device by two-dimensional electron gas for terahertz application.

Author

Dai, Yang, Li, Yukun, Gao, Leiyu, Zuo, Jing, Zhang, Biying, Chen, Cheng, Wang, Zhongxu, and Zhao, Wu

Abstract

A novel bilateral impact-ionization-avalanche-transit-time (BIMPATT) diode based on AlGaN/GaN two-dimensional electron gas is proposed in this article. The BIMPATT is compatible with the available GaN high electron mobility transistor (HEMT) manufacturing process and has a shorter actual electron transit distance than existing HEMT-like IMPATT (HIMPATT) diodes. Compared with the same-sized HIMPATT, the optimum frequency of BIMPATT rises from 320 to 420 GHz and possesses a far wider operating frequency band, especially in the near 0.9 THz range. The maximum DC-RF conversion efficiency rises from 12.9% to 17.6%. The maximum RF power of BIMPATT is 3.18 W/mm, which is similar to 3.12 W/mm of the HIMPATT. Furthermore, our simulation demonstrated that the characteristics of BIMPATT are significantly affected by the length of anode and the thickness of the AlGaN barrier layer. The effects of ohmic contact resistance and background impurities on BIMPATT are also taken into account. This paper provides a reference for the design and characteristics enhancement of the lateral IMPATT devices. [ABSTRACT FROM AUTHOR]

Published

2024

189. Magnetic properties of Fe56Pd44−xGdx thin films.

Author

Sahari, Mohamed Abdennour, Olivetti, Elena Sonia, Magni, Alessandro, Fiore, Gianluca, Boudissa, Mokhtar, Tiberto, Paola, Bahamida, Saida, and Coïsson, Marco

Abstract

In this paper, we have studied the effect on the structure and magnetic properties of partial Pd substitution by Gd in Fe–Pd thin films of nominal composition Fe56Pd44−xGdx (x = 1, 3, 5, and 7), deposited onto Si(100) and Si(100)/SiO2 substrates by thermal evaporation. Several techniques contribute to the characterization of their microstructure and magnetic properties, such as x-ray diffraction (XRD), scanning electron microscopy, alternating gradient field magnetometry, and magnetic force microscopy (MFM). X-ray diffraction shows that the as-deposited films are either amorphous or contain a disordered FePd phase, depending on the film thickness. The transformation of disordered fcc-FePd into ordered fct-FePd has been induced by a heat treatment at 530 °C for 4 h. The addition of gadolinium leads to a reduction in the coercivity as a consequence of the emergence of soft phases and of the progressive reduction of the fct-FePd phase, which is primarily responsible for the observed maze magnetic domains. The exchange coupling between the soft phase and the hard fct-FePd phase is demonstrated by first-order reversal curves (FORCs). [ABSTRACT FROM AUTHOR]

Published

2024

190. Plasma assisted remediation of SiC surfaces.

Author

Mathews Jr., M. A., Graves, A. R., Boris, D. R., Walton, S. G., and Stinespring, C. D.

Abstract

This paper describes a three-step process to remediate surface and sub-surface defects on chemo-mechanically polished SiC surfaces. In this process, a CF4-based inductively coupled plasma with reactive ion etch was used to remove material to a depth, which is unaffected by surface and subsurface polishing damage. This produced a planarized but carbon-rich fluorinated surface. This surface was then exposed to a 2 min rapid thermal oxidation in air at 1000 °C to oxidize and volatilize the excess carbon and fluorinated species, respectively. The resulting surface oxide was then stripped using a dilute hydrofluoric acid in water solution. This process, referred to as plasma assisted remediation, reproducibly yielded planarized, stoichiometric surfaces with low levels of carbon and oxygen contamination suitable for subsequent device fabrication. In the supporting studies described here, 4H- and 6H-SiC(0001) surfaces were remediated and characterized by x-ray photoelectron spectroscopy and atomic force microscopy at each stage of the process. Experimental studies under ion-rich and radical-dominant conditions are also reported which provide greater insight into the underlying chemistry and physics of the process. [ABSTRACT FROM AUTHOR]

Published

2024

191. Merging of TM-polarized bound states in the continuum in leaky-mode photonic lattices.

Author

Lee, Sun-Goo, Kim, Seong-Han, Suk Hong, Kee, and Lee, Wook-Jae

Abstract

Optical eigenstates with a high quality (Q) factor provide substantial advantages for a broad spectrum of optical devices, particularly those demanding strong light–matter interactions. Recently, it has been demonstrated that ultrahigh- Q resonances can be realized in planar photonic structures by merging multiple bound states in the continuum (BICs) in the momentum space. Photonic lattices with thin-film geometry are known to support abundant TE-polarized and TM-polarized BICs. While prior research has explored the merging of TE-polarized BICs, this paper presents analytical and numerical results concerning the merging of TM-polarized BICs in laterally periodic one-dimensional photonic lattices. As the thickness of photonic lattices increases, TM-polarized accidental BICs descend along the dispersion curves and eventually merge at the upper edge of the second stop band. Employing coupled-mode analysis, we calculate the analytical merging thickness at which multiple TM-polarized BICs come together at the second-order Γ point. We confirm the merging of TM-polarized BICs through finite-element method simulations. Our results can be beneficial for achieving ultrahigh- Q resonances through the merging of BICs. [ABSTRACT FROM AUTHOR]

Published

2024

192. Measurement of coating–substrate interface stiffness using a constructed ultrasonic echo phase derivative spectrum.

Author

Qi, Tianzhi, Lin, Li, Ma, Zhiyuan, Yang, Jiwei, and Zhao, Yang

Subjects

ECHO, ULTRASONICS, ULTRASONIC welding, CARBON steel, REFLECTANCE

Abstract

Measurement of coating–substrate interface stiffness can indirectly characterize interface bonding quality. This paper proposes a noval quantitative inversion coating–substrate interface stiffness method based on the multi-resonance frequencies of a constructed ultrasonic echo phase derivative spectrum (UEPDS). The theoretical relationship between UEPDS resonance frequencies and interface stiffness is derived. The detection frequency and high-sensitivity interface stiffness range are optimized based on the sensitivity analyzed. Numerical simulation and experiment are implemented on a 0.48 mm aluminum layer/carbon steel substrate specimen to prove the validity of the proposed ultrasonic method. The simulation results show that the maximal relative error between the inversion and the preset interface stiffnesses is reduced from 23% to 8% compared with the traditional ultrasonic reflection coefficient amplitude spectrum-based (URCAS-based) method. The experiment results indicate that the UEPDS-based inversion interface stiffnesses have the same trend as the nominal contact pressures between the coating–substrate interface. [ABSTRACT FROM AUTHOR]

Published

2024

193. Analysis and modeling of the influence of gate leakage current on threshold voltage and subthreshold swing in p-GaN gate AlGaN/GaN high electron mobility transistors.

Author

Liu, Kai, Wang, Chong, Zhang, Kuo, Ma, Xiaohua, Bai, Junchun, Zheng, Xuefeng, Li, Ang, and Hao, Yue

Subjects

THRESHOLD voltage, MODULATION-doped field-effect transistors, STRAY currents, GALLIUM nitride, METALWORK, FIELD-effect transistors, SCHOTTKY barrier

Abstract

In this paper, the p-GaN gate AlGaN/GaN high electron mobility transistors (HEMTs) with varying combinations of gate metal work function and gate geometry are fabricated and investigate the influence of gate leakage current (IGS) on the threshold voltage (VTH) and subthreshold swing (SS). The unique dependence of VTH and SS on gate geometry for different metals is observed, which is different from traditional field-effect transistors. A novel hybrid physics model, consisting of the traditional capacitance divider model and hole injection model, is proposed to explain this phenomenon, and the results exhibit an excellent agreement with the experimental data. The holes traverse the gate/p-GaN Schottky barrier by thermal emission or tunneling and inject into the p-GaN layer, generating the IGS. Expanding upon the traditional capacitance divider model, a portion of the injected holes accumulate at the p-GaN/AlGaN interface and induce the corresponding electrons at the AlGaN/GaN heterojunction, which promotes channel conduction. Hence, the transfer curves display the correlation between IGS and VTH as well as SS. The results show that high IGS can alleviate the instability of VTH caused by the lithographic overlay error, and simultaneously optimize SS. This work offers a novel perspective for examining the turn-on mechanism of p-GaN HEMTs, thereby contributing to device design. [ABSTRACT FROM AUTHOR]

Published

2024

194. A wideband high-gain dielectric resonator antenna based on mullite microwave dielectric ceramics.

Author

Du, Chao, Bao, Ziyan, Chen, Hetuo, Zhou, Guohong, Pang, Yongqiang, Liu, Haiwen, Jiang, Huangfu, Zhou, Tao, Xia, Song, and Zhou, Di

Subjects

DIELECTRIC resonator antennas, MICROWAVE devices, MULLITE, MICROWAVES, DIELECTRICS, DIELECTRIC properties

Abstract

In this paper, the high-quality factor mullite microwave dielectric ceramic is employed to introduce in dielectric resonator antenna (DRA). The microwave dielectric properties of ɛr ∼ 5.8, Q × f ∼ 31 240 at 9.66 GHz, and loss tangent tanδ = 1/Q ∼ 2.7 × 10−4 can be obtained by the solid-state reaction method in mullite microwave dielectric ceramic sintered at 1700 °C. On this basis, the resonant modes of the proposed broadband high-gain rectangular DRA are analyzed by using a dielectric waveguide theoretical model and the antenna performance is evaluated by a commercial CST Microwave Studio 2021® software. It has been found that the proposed rectangular DRA can provide a broad bandwidth of 35.9%, a maximum gain of 10 dBi at 3.61 GHz, and a radiation efficiency of 90% in the range of 3.13–4.42 GHz. For demonstration, adequate consistency between the simulation results and the measurement results was achieved. The proposed DRA has great application potential and value in 5G communication scenarios requiring wideband and high-gain antenna. [ABSTRACT FROM AUTHOR]

Published

2024

195. Electromagnetic absorption properties of FexCoNi magnetic nano particles.

Author

Li, Hong, Li, Hongyang, Yang, Feng, Cai, Qing, Xu, Wenqi, Wang, Ran, and Liu, Ying

Subjects

MAGNETIC permeability, MAGNETIC properties, PERMITTIVITY, MAGNETIC particles, MAGNETIC flux leakage, DIELECTRIC loss

Abstract

The microstructure morphology, static magnetic properties, and electromagnetic absorption characteristics of nano FexCoNi alloy particles prepared by chemical liquid deposition with five different Fe content levels are investigated in this paper. The results show that spherical FexCoNi alloy particles with an average particle size of about 100–200 nm and a face-centered cubic crystal structure were obtained. All five samples exhibited soft magnetic behavior, with the saturation magnetization intensity showing an increasing-then-decreasing trend with increasing Fe content, peaking at 141.8 emu/g for Fe content x = 1.0. The dielectric constants (real and imaginary parts) of the prepared alloy particles exhibit significant differences with respect to the variation of Fe content, while the changes in the real and imaginary parts of the magnetic permeability show less pronounced effects with increasing Fe content. As the electromagnetic wave frequency increases, the real parts of the dielectric constants for all composites show minimal fluctuations, and the real parts of the magnetic permeability exhibit a decreasing trend. Moreover, the imaginary parts of the dielectric constants and magnetic permeability show an increasing followed by a decreasing trend as the frequency rises. The material with Fe content x = 1 demonstrated optimal dielectric loss performance and relatively excellent magnetic loss performance, with a sample thickness of 1.9 mm exhibiting the highest reflection loss (RLmax) of −24.2 dB and an effective absorption bandwidth of 4.48 GHz. [ABSTRACT FROM AUTHOR]

Published

2024

196. A ternary complementary Gray code phase unwrapping method in fringe projection profilometry.

Author

Wei, Hao, Li, Hongru, Liu, Jiangtao, Deng, Guoliang, and Zhou, Shouhuan

Subjects

GRAY codes, PHASE coding, BINARY codes

Abstract

This paper proposes a phase unwrapping method based on ternary Gray code in fringe projection profilometry. This method does not require additional projection images or any prior knowledge. It accurately determines the segmentation thresholds of the ternary Gray code using only the average intensity and intensity modulation calculated from phase-shifting fringes, effectively reducing projection costs and achieving lower codeword errors. Additionally, a segment selection strategy suitable for the ternary Gray code is proposed. By employing the complementary method, three sets of candidate orders with certain codeword shifts can be generated. The wrapped phase is then divided into three segments: upper, middle, and lower segments, and correspondingly matched with the central regions of the three sets of candidate orders, thus enabling the solution of the absolute phase. Through the segment selection strategy, error-prone areas at the edges of orders are effectively avoided, further enhancing the accuracy of measurement results. Compared to the binary Gray code, the ternary complementary Gray code can encode up to 3 m − 1 orders when the number of Gray code patterns is m; when the required number of encoding orders is K, only ⌈ log 3 K ⌉ + 1 Gray code patterns are needed. Its additional value capacity precisely enables it to encode more orders, thereby increasing the frequency of phase-shifting fringes and further enhancing measurement efficiency. A series of experiments validates the feasibility, robustness, and superiority of this method. [ABSTRACT FROM AUTHOR]

Published

2024

197. Amplitude and phase modulation with electric quadrupole radiation.

Author

Zhang, Jiawei, Shi, Weijie, Liu, Andong, Tang, Lili, Zhang, Shuyan, and Dong, Zhenggao

Subjects

PHASE modulation, QUADRUPOLES, RADIATION, REFRACTION (Optics), GEOMETRIC quantum phases

Abstract

Optical metasurfaces can be used to realize various peculiar optical effects, and their mechanisms of the controlling optical phase can be roughly categorized into three types: resonant phase, geometric phase, and propagation phase, also known as the dynamic phase. Multiple mechanisms can be employed to manipulate the phase and amplitude of one metasurface. Therefore, discovering more profound and diverse methods can provide additional degrees of application freedom. This paper proposes a control principle based on electric multipole expansion. We found that for a unit structure formed by dual-metal bars on a metasurface, the radiation of its dipole is equivalent to the interference results of the dual-metal bars. Moreover, the radiation of the quadrupole enables independent control for amplitude and phase. Therefore, we used quadrupole radiation to manipulate the phase and amplitude of the light and even investigated some simple applications, including the realization of focusing light and anomalous refraction. Such a new mechanism of controlling light, combined with other methods, can provide significant insights into achieving challenging goals, like steganography and multifunctional metasurfaces. [ABSTRACT FROM AUTHOR]

Published

2024

198. A multi-party verifiable quantum proxy signature scheme based on quantum teleportation.

Author

Wang, Chengxiang, Lu, Dianjun, Tian, Fuyao, and Yao, Weixin

Subjects

QUANTUM teleportation, PROBLEM solving, CRYPTOGRAPHY

Abstract

With the development of science and technology and the appearance of various special conditions that cause signers to be unable to sign, proxy signature is gradually becoming a hot spot in cryptography research. This paper combines proxy signature, quantum teleportation, and multi-party verification and proposes a multi-party verifiable quantum proxy signature scheme based on quantum teleportation. This scheme has the following characteristics: The authentication method based on the H a s h function can effectively solve the problem of identity identification among members; in order for the proxy signer to be able to verify the correctness of the proxy authorization, a form of proxy signature authorization that concatenates the identity information of the original signer is used. The security analysis shows that our scheme is unforgeable and undeniable and can resist intercept-resend attacks and cheating attacks. [ABSTRACT FROM AUTHOR]

Published

2024

199. Structurally tunable acoustic transmission-coded metamaterials.

Author

Cui, Qinghao, Wang, Jilai, Tang, Xuefeng, Li, Quhao, Men, Junhui, and Wan, Yi

Subjects

SOUND waves, METAMATERIALS, FRESNEL lenses, PLANE wavefronts, SPACE frame structures, TRANSMISSION of sound

Abstract

The introduction of metasurfaces has renewed Snell's law, and the metasurfaces can manipulate sound waves flexibly. In this paper, a coding metasurface with a simple and adjustable coding unit for sound wave transmission is proposed. By changing the orientation of a movable part in a fixed structure, conversion is achieved between two types of units with a phase difference of 180° and high transmittance (>75%). By combining the two types of units, the phases of sound waves can be regulated dynamically. Structural simulations are performed using finite-element software, and the beam splitting of the transmitted sound wave is verified by theoretical analysis and experiments under plane wave incidence in the frequency range of 4.7–5.7 kHz. In addition, the two types of units are used to design a coding Fresnel lens, and its simulated focusing performance is verified by experiments at 4.7–5.7 kHz. [ABSTRACT FROM AUTHOR]

Published

2024

200. Investigation of the areas with high D07-band emission in multicrystalline silicon wafers using electron microscopy and hyperspectral photoluminescence imaging.

Author

Thøgersen, Annett, Jensen, Ingvild J. T., Mehl, Torbjørn, Burud, Ingunn, Olsen, Espen, Gudem Ringdalen, Inga, Zhu, Junjie, and Søndenå, Rune

Subjects

SILICON wafers, SCANNING transmission electron microscopy, SILICON solar cells, FOCUSED ion beams, PHOTOLUMINESCENCE, PHOTOLUMINESCENCE measurement

Abstract

This paper explores the fundamental structural origins of the 0.7 eV band emission peak, known as D07. The increased attention on these d-band emission lines originates mainly from the correlation between crystal defect and the intensified recombination of less dominant charge carriers. This association holds substantial importance, impacting not just the electronics sector but also raising concerns about reduced efficiency in silicon solar cells. By employing hyperspectral photoluminescence imaging, we pinpointed regions manifesting high D07 peak emissions on a microscopic scale. Subsequently, we conducted a structural investigation utilizing scanning electron microscopy and electron backscatter diffraction. Following this, we used a focused ion beam to extract areas of interest, allowing for a detailed characterization of the sample using high-resolution scanning transmission electron microscopy at the atomic scale. This approach aids in identifying defects and determining grain boundary orientation. In areas of high D07 band emission, we found Σ 3 { 114 } { 101 } grain boundaries decorated with two-layer fault twin and/or an extrinsic two-layer stacking faults. In addition, density functional theory calculations suggest oxygen impurities as a possibility for substitutional segregation to these types of defects. It is therefore plausible that the D07 line might be attributed to stacking faults featuring oxygen agglomerates. [ABSTRACT FROM AUTHOR]

Published

2024