Wave function properties of a single and a system of magnetic flux tube(s) oscillations

Esmaeili, Shahriar; Nasiri, Mojtaba; Dadashi, Neda; Safari, Hossein

doi:10.1002/2016ja022848

Cited by 8 publications

(7 citation statements)

References 52 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The dispersion mechanisms considered in this simulation are due to the acoustic phonon dispersion, polar optical phonon, ionized impurities, and the dispersion of non-polar optical phonons. [12][13][14][15]. The elastic dispersion of ionized impurities is also considered by the Coulomb Potential of Brooks-Herring type [16][17][18].…”

Section: Simulation Methodsmentioning

confidence: 99%

Assessment of Monte Carlo Simulation of Electron Transport in ZnO Diode in Intelligent Information Systems

Adeleh¹,

Reza²

2019

IJIIS

View full text Add to dashboard Cite

Aim: The interest to study electron transport in semiconductor devices at very high electric field has been increased in the last decades and assessment of Monte Carlo simulation of electron transport in ZnO diode in intelligent information systems is of high significance. Method: The Monte Carlo method as applied to semiconductor transport is a simulation of the trajectories of individual Carriers as they move through a device under the influence of external forces and subject to random scattering events. Monte Carlo simulation is performed to study quasi-ballistic transport of electrons in n + nn + ZnO diode. Result: In this simulation, the spatial motion of the electrons is semi classical and the scattering mechanisms taken into account are those due to acoustic phonons, non-polar optical phonons, polar optical phonons and ionized impurities. The simulation results are reported for different temperatures and voltages. Conclusion: It is also found that the transient properties of ZnO-made diode are not much sensitive to environment temperature changes, and thus the use of this substance is highly recommended in manufacture of electronic equipment.

show abstract

Section: Simulation Methodsmentioning

confidence: 99%

Assessment of Monte Carlo Simulation of Electron Transport in ZnO Diode in Intelligent Information Systems

Adeleh¹,

Reza²

2019

IJIIS

View full text Add to dashboard Cite

show abstract

“…Each subdomain is represented by a set of element equations to the original problem. The domains type to perform the (FEM) solution is free tetrahedral [21].Using this method, punch, holder and die are modeled as discrete rigid parts and FG sheet as deformable par and 8 layers which each layer has its mechanical properties using exponential law distribution. The bottom layer is pure aluminum1100 alloy and top layer is pure copper10100 alloy.…”

Section: Results Of Finite Element Methodsmentioning

confidence: 99%

Simulation and Analysis of Deep Drawing Process of the Functionally Graded Sheet

Hashempoor¹

2019

MJMIE

View full text Add to dashboard Cite

In this paper, deep drawing process of functionally graded sheet is investigated analytically and using finite element method. Using equations for deep drawing of isotropic sheets and governing equations of functionally graded materials, equations for deep drawing of functionally graded sheets are derived. Mechanical properties of the functionally graded sheet vary through the thickness of it according to the exponential law distribution. Punch force and axial stresses at the wall are calculated by this analytical method. Also, using this force in abaqus software, axial stresses at the wall are determined. The results of two methods were compared with each other and good agreement was obtained.

show abstract

“…In this semi-classical method, carriers are considered as classical particles, which are influenced by various dispersion processes. A new numerical method for solving a PDE as wave equation and extracting its different oscillating modes was implemented by Esmaeili et al [15]. The dispersion mechanisms considered in this simulation are due to the acoustic phonon dispersion, polar optical phonon, ionized impurities, and the dispersion of non-polar optical phonons.…”

Section: Simulation Methodsmentioning

confidence: 99%

Evaluating of Simulating the Transportation of Electron in Intelligent Information Systems and High-Tech Applicants

Skafida¹

2019

View full text Add to dashboard Cite

The interest to study electron transport in semiconductor devices at very high electric field has been increased in the last decades and assessment of Monte Carlo simulation of electron transport in ZnO diode in intelligent information systems is of high significance. The Monte Carlo method as applied to semiconductor transport is a simulation of the trajectories of individual Carriers as they move through a device under the influence of external forces and subject to random scattering events. Monte Carlo simulation is performed to study quasi-ballistic transport of electrons in n + nn + ZnO diode. In this simulation, the spatial motion of the electrons is semi classical and the scattering mechanisms taken into account are those due to acoustic phonons, non-polar optical phonons, polar optical phonons and ionized impurities. The simulation results are reported for different temperatures and voltages. It is also found that the transient properties of ZnO-made diode are not much sensitive to environment temperature changes, and thus the use of this substance is highly recommended in manufacture of electronic equipment.

show abstract

Wave function properties of a single and a system of magnetic flux tube(s) oscillations

Cited by 8 publications

References 52 publications

Assessment of Monte Carlo Simulation of Electron Transport in ZnO Diode in Intelligent Information Systems

Assessment of Monte Carlo Simulation of Electron Transport in ZnO Diode in Intelligent Information Systems

Simulation and Analysis of Deep Drawing Process of the Functionally Graded Sheet

Evaluating of Simulating the Transportation of Electron in Intelligent Information Systems and High-Tech Applicants

Contact Info

Product

Resources

About