Search

Your search keyword '"Zubair, Muhammad"' showing total 1,936 results
Start Over Author "Zubair, Muhammad" Search Limiters Available in Library Collection
1,936 results on '"Zubair, Muhammad"'

1. Weyl semimetal phases and intrinsic spin-Hall conductivity in SbAs ordered alloys

Author

Zubair, Muhammad, Ho, Dai Q., To, Duy Quang, Khalid, Shoaib, and Janotti, Anderson

Subjects
Condensed Matter - Materials Science
Abstract

Using density functional theory calculations we investigated possible Weyl semimetal (WSM) phases in antimony arsenide ordered alloys Sb1-xAsx (x=0, 1/6, 1/3, 1/2, 2/3, 5/6, 1). We find WSM phases for all As compositions of Sb1-xAsx with broken inversion symmetry, in contrast to Bi1-xSbx where only compositions x=1/2 and 5/6 were predicted to exhibit WSM phases. The WSM phases in Sb1-xAsx are characterized by the presence of 12 Weyl points, located within 55 meV from the Fermi level in the case of x=1/2. The robust spin-orbit coupling strength and Berry curvature in these alloys produce large spin-Hall conductivity in the range of 176-602 (hbar/e)(S/cm), comparable to that in the BiSb alloys. Finally, Sb0.5As0.5 is predicted to be almost lattice-matched to GaAs(111), with the Fermi level within the gap of the semiconductor, facilitating growth and characterization, and thus, offering promising integration with conventional semiconductors.

Published
2025

2. Second Harmonic Generation in Topological Insulators under Quantizing Magnetic Fields

Author

Chang, Kainan, Zubair, Muhammad, Cheng, Jin Luo, and Tse, Wang-Kong

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We theoretically investigate the second harmonic generation (SHG) of topological insulator surface states in a perpendicular magnetic field. Our theory is based on the microscopic expression of the second-order magneto-optical conductivity developed from the density matrix formalism, taking into account hexagonal warping effects on the surface states' band structure. Using numerically exact Landau level energies and wavefunctions including hexagonal warping, we calculate the spectrum of SHG conductivities under normal incidence for different values of magnetic field and chemical potential. The imaginary parts of the SHG conductivities show prominent resonant peaks corresponding to one-photon and two-photon inter-Landau level transitions. Treating the hexagonal warping term perturbatively, these transitions are clarified analytically within a perturbation theory from which approximate selection rules for the allowable optical transitions for SHG are determined. Our results show extremely high SHG susceptibility that is easily tunable by magnetic field and doping level for topological surface states in the far-infrared regime, exceeding that of many conventional nonlinear materials. This work highlights the key role of hexagonal warping effects in generating second-order optical responses and provides new insights on the nonlinear magneto-optical properties of the topological insulators.

Published
2024

12. Shadow of novel rotating black holes in GR coupled to nonlinear electrodynamics and constraints from EHT results

Author

Raza, Muhammad Ali, Sarikulov, Furkat, Rayimbaev, Javlon, Zubair, Muhammad, Ahmedov, Bobomurat, and Stuchlik, Zdenek

Subjects
General Relativity and Quantum Cosmology
Abstract

We study the optical properties of spacetime around a novel regular black hole (BH) in general relativity (GR) coupled to nonlinear electrodynamics (NED), which is asymptotically flat. First, we study the angular velocity and Lyapunov exponent in unstable photon circular orbits in the novel spherically symmetric BH spacetime. Later, the rotating regular BH solution is obtained using the Newmann-Janis algorithm, and the event horizon properties of the BH are determined. We analyze the effective potential for the circular motion of photons in the spacetime of the novel rotating BH. Also, we analyze the photon sphere around the novel BH and its shadow using celestial coordinates. We obtain that an increase of the BH spin and charge as well as NED field nonlinearity parameters causes an increase in the distortion parameter of the BH shadow, while, the area of the shadow and its oblateness decrease. Moreover, we also obtain the constraint values for the BH charge and the nonlinearity parameters using Event Horizon Telescope data from shadow sizes of supermassive BHs Sgr A* and M87*. Finally, the emission rate of BH evaporation through Hawking radiation is also studied.

Published
2023

13. Large Rashba splittings in bulk and monolayer of BiAs

Author

Zubair, Muhammad, Evangelista, Igor, Khalid, Shoaib, Medasani, Bharat, and Janotti, Anderson

Subjects
Condensed Matter - Materials Science, Physics - Computational Physics
Abstract

Two-dimensional materials with Rashba split bands near the Fermi level are key to developing upcoming next-generation spintronics. They enable generating, detecting, and manipulating spin currents without an external magnetic field. Here, we propose BiAs as a novel layered semiconductor with large Rashba splitting in bulk and monolayer forms. Using first-principles calculations, we determined the lowest energy structure of BiAs and its basic electronic properties. Bulk BiAs has a layered crystal structure with two atoms in a rhombohedral primitive cell, similar to the parent Bi and As elemental phases. It is a semiconductor with a narrow and indirect band gap. The spin-orbit coupling leads to Rashba-Dresselhaus spin splitting and characteristic spin texture around the L-point in the Brillouin zone of the hexagonal conventional unit cell, with Rashba energy and Rashba coupling constant for valence (conduction) band of $E_R$= 137 meV (93 meV) and $\alpha_R$= 6.05 eV\AA~(4.6 eV{\AA}). In monolayer form (i.e., composed of a BiAs bilayer), BiAs has a much larger and direct band gap at $\Gamma$, with a circular spin texture characteristic of a pure Rashba effect. The Rashba energy $E_R$= 18 meV and Rashba coupling constant $\alpha_R$= 1.67 eV{\AA} of monolayer BiAs are quite large compared to other known 2D materials, and these values are shown to increase under tensile biaxial strain., Comment: 15pages,9figures

Published
2023

14. Treatment Planning Strategies for Interstitial Ultrasound Ablation of Prostate Cancer.

Author

Gupta, Pragya, Heffter, Tamas, Zubair, Muhammad, Hsu, I-Chow, Burdette, E, and Diederich, Chris

Subjects
Bioacoustic-thermal models, interstitial ultrasound, prostate cancer, thermal therapy, treatment planning
Abstract

PURPOSE: To develop patient-specific 3D models using Finite-Difference Time-Domain (FDTD) simulations and pre-treatment planning tools for the selective thermal ablation of prostate cancer with interstitial ultrasound. This involves the integration with a FDA 510(k) cleared catheter-based ultrasound interstitial applicators and delivery system. METHODS: A 3D generalized prostate model was developed to generate temperature and thermal dose profiles for different applicator operating parameters and anticipated perfusion ranges. A priori planning, based upon these pre-calculated lethal thermal dose and iso-temperature clouds, was devised for iterative device selection and positioning. Full 3D patient-specific anatomic modeling of actual placement of single or multiple applicators to conformally ablate target regions can be applied, with optional integrated pilot-point temperature-based feedback control and urethral/rectum cooling. These numerical models were verified against previously reported ex-vivo experimental results obtained in soft tissues. RESULTS: For generic prostate tissue, 360 treatment schemes were simulated based on the number of transducers (1-4), applied power (8-20 W/cm2), heating time (5, 7.5, 10 min), and blood perfusion (0, 2.5, 5 kg/m3/s) using forward treatment modelling. Selectable ablation zones ranged from 0.8-3.0 cm and 0.8-5.3 cm in radial and axial directions, respectively. 3D patient-specific thermal treatment modeling for 12 Cases of T2/T3 prostate disease demonstrate applicability of workflow and technique for focal, quadrant and hemi-gland ablation. A temperature threshold (e.g., Tthres = 52 °C) at the treatment margin, emulating placement of invasive temperature sensing, can be applied for pilot-point feedback control to improve conformality of thermal ablation. Also, binary power control (e.g., Treg = 45 °C) can be applied which will regulate the applied power level to maintain the surrounding temperature to a safe limit or maximum threshold until the set heating time. CONCLUSIONS: Prostate-specific simulations of interstitial ultrasound applicators were used to generate a library of thermal-dose distributions to visually optimize and set applicator positioning and directivity during a priori treatment planning pre-procedure. Anatomic 3D forward treatment planning in patient-specific models, along with optional temperature-based feedback control, demonstrated single and multi-applicator implant strategies to effectively ablate focal disease while affording protection of normal tissues.

Published
2024

16. Reconfigurable Intelligent Surfaces: Interplay of Unit-Cell- and Surface-Level Design and Performance under Quantifiable Benchmarks

Author

Rafique, Ammar, Hassan, Naveed Ul, Zubair, Muhammad, Naqvi, Ijaz Haider, Mehmood, Muhammad Qasim, Yuen, Chau, Di Renzo, Marco, and Debbah, Merouane

Subjects
Computer Science - Information Theory, Electrical Engineering and Systems Science - Signal Processing
Abstract

The ability of reconfigurable intelligent surfaces (RIS) to produce complex radiation patterns in the far-field is determined by various factors, such as the unit-cell's size, shape, spatial arrangement, tuning mechanism, the communication and control circuitry's complexity, and the illuminating source's type (point/planewave). Research on RIS has been mainly focused on two areas: first, the optimization and design of unit-cells to achieve desired electromagnetic responses within a specific frequency band; and second, exploring the applications of RIS in various settings, including system-level performance analysis. The former does not assume any specific radiation pattern on the surface level, while the latter does not consider any particular unit-cell design. Both approaches largely ignore the complexity and power requirements of the RIS control circuitry. As we progress towards the fabrication and use of RIS in real-world settings, it is becoming increasingly necessary to consider the interplay between the unit-cell design, the required surface-level radiation patterns, the control circuit's complexity, and the power requirements concurrently. In this paper, a benchmarking framework for RIS is employed to compare performance and analyze tradeoffs between the unit-cell's specified radiation patterns and the control circuit's complexity for far-field beamforming, considering different diode-based unit-cell designs for a given surface size. This work lays the foundation for optimizing the design of the unit-cells and surface-level radiation patterns, facilitating the optimization of RIS-assisted wireless communication systems.

Published
2023

17. Rate dependence of damage formation in metallic-intermetallic Mg-Al-Ca composites

Author

Medghalchi, Setareh, Zubair, Muhammad, Karimi, Ehsan, Sandlöbes-Haut, Stefanie, Kerzel, Ulrich, and Korte-Kerzel, Sandra

Subjects
Condensed Matter - Materials Science
Abstract

We study a cast Mg-4.65Al-2.82Ca alloy with a microstructure containing $\alpha$-Mg matrix reinforced with a C36 Laves phase skeleton. Such ternary alloys are targeted for elevated temperature applications in automotive engines since they possess excellent creep properties. However, in application, the alloy may be subjected to a wide range of strain rates and in material development, accelerated testing is often of essence. It is therefore crucial to understand the effect of such rate variations. Here, we focus on their impact on damage formation. Due to the locally highly variable skeleton forming the reinforcement in this alloy, we employ an analysis based on high resolution panoramic imaging by scanning electron microscopy coupled with automated damage analysis by deep learning-based object detection and classification convolutional neural network algorithm (YOLOV5). We find that with decreasing strain rate the dominant damage mechanism for a given strain level changes: at a strain rate of $5\cdot10^{-4}/s$ the evolution of microcracks in the C36 Laves phase governs damage formation. However , when the strain rate is decreased to $5\cdot10^{-6}/s$, interface decohesion at the $\alpha$-Mg/Laves phase interfaces becomes equally important. We also observe a change in crack orientation indicating an increasing influence of plastic co-deformation of the {\alpha}-Mg matrix and Laves phase. We attribute this transition in leading damage mechanism to thermally activated processes at the interface.

Published
2023

18. Inversion Symmetry Breaking in Epitaxial Ultrathin Bi (111) Films

Author

Inbar, Hadass S., Zubair, Muhammad, Dong, Jason T., Engel, Aaron N, Dempsey, Connor P., Chang, Yu Hao, Nishihaya, Shinichi, Khalid, Shoaib, Fedorov, Alexei V., Janotti, Anderson, and Palmstrøm, Chris J.

Subjects
Condensed Matter - Materials Science
Abstract

Bismuth (Bi) films hold potential for spintronic devices and topological one-dimensional edge transport. Large-area high-quality (111) Bi ultrathin films are grown on InSb (111)B substrates. Strong film-substrate interactions epitaxially stabilize the (111) orientation and lead to inversion symmetry breaking. We resolve the longstanding controversy over the Z_2 topological assignment of bismuth and show that the surface states are topologically trivial. Our results demonstrate that interfacial bonds prevent the semimetal-to-semiconductor transition predicted for freestanding bismuth layers, highlighting the importance of controlled functionalization and surface passivation in two-dimensional materials.

Published
2023

19. Short path molecular distillation of the essential oil from Pinus roxburghii oleoresin affords volatile fractions with powerful antioxidant and antimicrobial activities comparable with common synthetic agents and antimicrobials

Author

Ayub, Muhammad Adnan, Amin, Hawraz Ibrahim M., Waseem, Rameen, Amin, Kamaran Younis M., Hanif, Muhammad Asif, Hussain, Amjad, Issa, Kovan Dilawar, Ramírez, Jorge, Armijos, Chabaco, Zubair, Muhammad, and Vidari, Giovanni

Published
2025
Full Text
View/download PDF

23. Generalized Fully Coherent Closed-form Receiver Design for Joint Radar and Communication System

Author

Zubair, Muhammad, Ahmed, Sajid, and Alouini, Mohamed-Slim

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

In conventional radar, the transmission of the same waveform is repeated after a predefined interval of time called pulse-repetition-interval (PRI). This technique helps to estimate the range and Doppler shift of targets and suppress clutter. In dual-function radar communication (DFRC), different waveforms are transmitted after each PRI. Thus, each waveform yields different range-side-lobe (RSL) levels at the receiver's output. As a consequence, Doppler shift estimation and clutter suppression become challenging tasks. A state-of-the-art (SOTA) method claims that if the number of waveforms is more than two, it is impossible to achieve fully coherent RSL levels with both waveforms. Therefore, this algorithm uses iterative methods to achieve as much as possible coherency and minimize the RSL levels. In contrast to that SOTA method, we proposed two novel closed-form receivers for the DFRC that yield a fully coherent response for several waveforms and suppress the RSL levels. Experimental results demonstrate that the proposed receivers achieve full coherency and the RSL levels are significantly lower than the conventional method., Comment: 12 pages, 7 figures

Published
2021

24. Plastic deformation of the CaMg$_{2}$ C14-Laves phase from 50-250$^\circ$C

Author

Freund, Martina, Andre, Doreen, Zehnder, Christoffer, Rempel, Hanno, Gerber, Dennis, Zubair, Muhammad, Sandlöbes-Haut, Stefanie, Gibson, James S. K. -L., and Korte-Kerzel, Sandra

Subjects
Condensed Matter - Materials Science
Abstract

Intermetallic phases can significantly improve the creep resistance of magnesium alloys, extending their use to higher temperatures. However, little is known about the deformation behaviour of these phases at application temperatures, which are commonly below their macroscopic brittle-to-ductile-transition temperature. In this study, we therefore investigate the activation of different slip systems of the CaMg$_2$ phase and the occurrence of serrated yielding in the temperature range from 50$^\circ$C to 250$^\circ$C. A decreasing amount of serrated flow with increasing temperature suggests that solute atoms govern the flow behaviour when the CaMg$_{2}$ phase is off-stoichiometric., Comment: 24 pages, 10 figures

Published
2021

25. Harvesting the Crops of Ability Grouping Practice in Schools from the Field of Literature

Author

Zubair, Muhammad, Alam, Ambreen, and Dukmak, Samir

Abstract

Students of diverse abilities tend to be divided into groups that advocate academic homogeneity. Ability grouping practice is embedded within the contemporary hyper-accountability culture in education that has shifted the focus of the teaching community from promoting academic attainment in pupils to being highly ranked in the market-based education system. To maintain an ascending position and avoid "punitive measures, schools adopt stratification according to the pupils" academic abilities. Ability grouping strategy is commonplace in countries like the United States of America (USA), Canada, New Zealand, United Arab Emirates (UAE) and Australia, but the intensity of this practice is unfavourable. This study aims to visit the scholarly work of the authors of the western world to comprehend the history and the advances in the ability grouping practice. The collected data from several studies endorse that ability grouping leads educational establishments to inculcate diverse educational experiences and opportunities for learners. Thus, dividing learners into academic groups contributes to broadening the socioeconomic gap.

Published
2023
Full Text
View/download PDF

32. Unraveling the vector nature of generalized space-fractional Bessel beams

Author

Ehsan, Aqsa, Mehmood, Muhammad Qasim, Riaz, Kashif, Ang, Yee Sin, and Zubair, Muhammad

Subjects
Physics - Optics
Abstract

We introduce an exact analytical solution of the homogeneous space-fractional Helmholtz equation in cylindrical coordinates. This solution, called vector Space-Fractional Bessel Beam (SFBB), has been established from the Lorenz' gauge condition and Hertz vector transformations. We perform scalar and vector wave analysis focusing on electromagnetics applications, especially in cases where the dimensions of the beam are comparable to its wavelength $(k_r \approx k)$. The propagation characteristics such as the diffraction and self-healing properties have been explored with particular emphasis on the polarization states and transverse propagation modes. Due to continuous order orbital angular momentum dependence, this beam can serve as a bridge between the ordinary integer Bessel beam and the fractional Bessel beam and, thus, can be considered as a generalized solution of the space-fractional wave equation that is applicable in both integer and fractional dimensional spaces. The proposed SFBBs provide better control over the beam characteristics and can be readily generated using Digital Micromirror Devices (DMDs), Spatial Light Modulators (SLMs), metasurfaces, or spiral phase plates. Our findings offer new insights on electromagnetic wave propagation, thus paving a new route towards novel applications in optical tweezers, refractive index sensing, optical trapping, and optical communications.

Published
2021
Full Text
View/download PDF

37. Exploring the transfer of plasticity across Laves phase interfaces in a dual phase magnesium alloy

Author

Guénolé, Julien, Zubair, Muhammad, Roy, Swagata, Xie, Zhuocheng, Lipińska-Chwałek, Marta, Sandlöbes-Haut, Stefanie, and Korte-Kerzel, Sandra

Subjects
Condensed Matter - Materials Science
Abstract

The mechanical behaviour of Mg-Al alloys can be largely improved by the formation of an intermetallic Laves phase skeleton, in particular the creep strength. Recent nanomechanical studies revealed plasticity by dislocation glide in the (Mg,Al)$_2$Ca Laves phase, even at room temperature. As strengthening skeleton, this phase remains, however, brittle at low temperature. In this work, we present experimental evidence of slip transfer from the Mg matrix to the (Mg,Al)$_2$Ca skeleton at room temperature and explore associated mechanisms by means of atomistic simulations. We identify two possible mechanisms for transferring Mg basal slip into Laves phases depending on the crystallographic orientation: a direct and an indirect slip transfer triggered by full and partial dislocations, respectively. Our experimental and numerical observations also highlight the importance of interfacial sliding that can prevent the transfer of the plasticity from one phase to the other., Comment: 23 pages, 8 figures, 1 table

Published
2020
Full Text
View/download PDF

38. Long distance adiabatic wireless energy transfer via multiple coils coupling

Author

Huang, Wei, Qu, Xiaowei, Yin, Shan, Zubair, Muhammad, Guo, Chu, Xiong, Xianming, and Zhang, Wentao

Subjects
Physics - Applied Physics, Quantum Physics
Abstract

Recently, the wireless energy transfer model can be described as the Schrodinger equation [Annals of Physics, 2011, 326(3): 626-633; Annals of Physics, 2012, 327(9): 2245-2250]. Therefore, wireless energy transfer can be designed by coherent quantum control techniques, which can achieve efficient and robust energy transfer from transmitter to receiver device. In this paper, we propose a novel design of wireless energy transfer which obtains the longer distance, efficient and robust schematic of power transfer, via multiple states triangle crossing pattern. After our calculations, we demonstrate that our design can provide much longer transfer distance with relatively smaller decreasing in the transfer efficiency., Comment: 5 pages, 4 figures

Published
2020
Full Text
View/download PDF

39. SOS: Socially Omitting Selfishness in IoT for Smart and Connected Communities

Author

Rehman, Ghani ur, Ghani, Anwar, Zubair, Muhammad, Saeed, Muhammad Imran, and Singh, Dhananjay

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing
Abstract

Smart and Connected Communities (SCC) is an emerging field of Internet of Things (IoT), and it is having potential applications to improve human life. The improvement may be in terms of preservation, revitalization, livability, and sustainability of a community. The resources of the nodes and devices in the SCC have certain constraints that may not allow the devices and nodes to cooperate to save their resources such as memory, energy, and buffer, or simply maximize their performance. Thus, to stimulate the nodes to avoid selfish behavior, SSC needs a novel and well-organized solution to motivate nodes for cooperation. This article aims to resolve the issue of selfish behaviors in SCC and to encourage the nodes for cooperation. A novel mechanism Socially Omitting Selfishness (SOS) has been proposed to manage/eradicate selfishness using a socially-oriented election process. The election process elects different heads based on weight and cooperation (using VCG model). The election of heads and incentive mechanism encourages the nodes to show participation and behave as highly cooperative members of the community. Furthermore, an extended version of the Dempster-Shafer model has been used to discourage the selfish behavior of the participating nodes in the SOS scheme. It uses different monitoring and gateway nodes to efficiently employ the proposed scheme. A mathematical model has been developed for the aforementioned aspects and simulated through the NS2 simulation environment to analyze the performance of SOS. The results of the proposed scheme outperform the contemporary schemes in terms of average delivery delay, packet delivery ratio, throughput, and average energy., Comment: 25 Pages, 7 Figures, 7 Tables, 55 References

Published
2020

40. Honesty Based Democratic Scheme to Improve Community Cooperation for IoT Based Vehicular Delay Tolerant Networks

Author

Rehman, Ghani ur, Ghani, Anwar, Zubair, Muhammad, Ghayyure, Shahbaz Ahmad Khan, and Muhammad, Shad

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Networking and Internet Architecture
Abstract

Many Internet of things (IoT) applications have been developed and implemented on unreliable wireless networks like the Delay tolerant network (DTN), however, efficient data transfer in DTN is still an important issue for the IoT applications. One of the application areas of DTN is Vehicular Delay Tolerant Network (VDTN) where the network faces communication disruption due to lack of end-to-end relay route. It is challenging as some of the nodes show selfish behavior to preserve their resources like memory, and energy level and become non-cooperative. In this article, an Honesty based Democratic Scheme (HBDS) is introduced where vehicles with higher honesty level are elected as heads -- during the process. Vehicles involved in the process would maximize their rewards (reputation) through active participation in the network activities whereas nodes with non-cooperative selfish behavior are punished. The honesty level of the heads is analyzed using Vickrey, Clarke, and Groves (VCG) model. The mathematical model and algorithms developed in the proposed HBDS technique are simulated using the VDTNSim framework to evaluate their efficiency. The performance results show that the proposed scheme dominates current schemes in terms of packet delivery probability, packet delivery delay, number of packets drop, and overhead ratio., Comment: 19 Pages, 5 Figures, 6 Tables, 55 References

Published
2020

49. Sonication strategies toward volumetric ultrasound hyperthermia treatment using the ExAblate body MRgFUS system.

Author

Kim, Kisoo, Zubair, Muhammad, Adams, Matthew, Diederich, Chris J, and Ozhinsky, Eugene

Subjects
Magnetic Resonance Imaging, Phantoms, Imaging, Sonication, High-Intensity Focused Ultrasound Ablation, Thermometry, ExAblate body array, Hyperthermia, MR thermometry, MRgFUS, high intensity focused ultrasound, Biomedical Imaging, Clinical Sciences, Oncology & Carcinogenesis
Abstract

PurposeThe ExAblate body MRgFUS system requires advanced beamforming strategies for volumetric hyperthermia. This study aims to develop and evaluate electronic beam steering, multi-focal patterns, and sector vortex beamforming approaches in conjunction with partial array activation using an acoustic and biothermal simulation framework along with phantom experiments.MethodsThe simulation framework was developed to calculate the 3D acoustic intensity and temperature distribution resulting from various beamforming and scanning strategies. A treatment cell electronically sweeping a single focus was implemented and evaluated in phantom experiments. The acoustic and thermal focal size of vortex beam propagation was quantified according to the vortex modes, number of active array elements, and focal depth.ResultsTurning off a percentage of the outer array to increase the f-number increased the focal size with a decrease in focal gain. 60% active elements allowed generating a sonication cell with an off-axis of 10 mm. The vortex mode number 4 with 60% active elements resulted in a larger heating volume than using the full array. Volumetric hyperthermia in the phantom was evaluated with the vortex mode 4 and respectively performed with 100% and 80% active elements. MR thermometry demonstrated that the volumes were found to be 18.8 and 29.7 cm3, respectively, with 80% array activation producing 1.58 times larger volume than the full array.ConclusionsThis study demonstrated that both electronic beam steering and sector vortex beamforming approaches in conjunction with partial array activation could generate large volume heating for HT delivery using the ExAblate body array.

Published
2021

Catalog

Books, media, physical & digital resources
See catalog results