Journals Menu
Follow SCIRP
Contact us
+1 323-425-8868
customer@scirp.org
WhatsApp +86 18163351462(WhatsApp)
Click here to send a message to me 1655362766
Paper Publishing WeChat

Energy and Power Engineering

Energy and Power Engineering

Energy and Power Engineering

ISSN Print: 1949-243X
ISSN Online: 1947-3818
www.scirp.org/journal/epe
E-mail: epe@scirp.org
"Scaling Laws for Plasma Focus Machines from Numerical Experiments"
written by S. H. SAW, S. LEE,
published by Energy and Power Engineering, Vol.2 No.1, 2010
has been cited by the following article(s):
  • Google Scholar
  • CrossRef
[1] Argon Soft X-Ray Scaling Curves for the Amirkabir Plasma Focus Device
Journal of Fusion Energy, 2022
[2] ВОПРОСЫ АТОМНОЙ НАУКИ И ТЕХНИКИ. СЕРИЯ: ТЕРМОЯДЕРНЫЙ СИНТЕЗ
… АТОМНОЙ НАУКИ И …, 2022
[3] Update on the scientific status of the plasma focus
Plasma, 2021
[4] Research with plasma foci in countries of Asia, Africa, and Latin America
2020
[5] Using the Modified Lee Model Code to Calculate the Optimum Length of NiZn Ferrite to Enhance the DPF Argon SXR Emission
2020
[6] SUITABILITY OF LEE CODES TO FIT MATHER, FILLIPOV AND HYBRID DENSE PLASMA FOCUS MACHINES CURRENT WAVEFORM
2019
[7] The Effects of Ferrites on Dense Plasma Focus Device: Using a Modification to the Lee Model
2019
[8] Comparative numerical study of the dynamics, ion beam and flow energetics of fast and slow focus modes in a 2 kJ plasma focus operated in various gases
2019
[9] A Plasma Focus device as ultra-high dose rate pulsed radiation source. Part I: Primary electron beam characterization
2019
[10] Experimental Dependence of the Neutron Yield on the Discharge Current for Plasma Focus Chambers Filled with Deuterium and Deuterium–Tritium
2019
[11] Observation of Plasma Dynamics in Axial and Radial Phase of DPF Device with Varying Gas Pressure
2018
[12] The Effect of the Shape of the Anode Head on the Nitrogen Soft X-Ray Emission from a Dense Plasma Focus Device: a Numerical Investigation Using the Modified Lee Model Code Accompanied by Experiments
Journal of Fusion Energy, 2018
[13] A Numerical Study on the Ion Production in the INTI International University Plasma Focus Machine using Nitrogen Gas
2018
[14] Application of medium energy plasma focus device in study of radioisotopes
Physics Letters A, 2018
[15] Simulation and Characterization of a Dense Plasma Focus Device
2018
[16] Numerical Experiments on IR-MPF-100 Plasma Focus Operated in Neon and Deuterium Gases
Journal of Fusion Energy, 2017
[17] Numerical study on the variation of pressure on India Bhabha Atomic Research Center (BARC) and Imperial College plasma focus machines
AIP Conference Proceedings, 2017
[18] Modelling and Electrical Characteristics of the Thailand Plasma Focus-II (TPF-II)
2017
[19] Effect of the Variation of Pressure on the Dynamics and Neutron Yield of Plasma Focus Machines
2017
[20] The Plasma Focus—Numerical Experiments, Insights and Applications
Plasma Science and Technology for Emerging Economies, 2017
[21] PF1000 High-Energy Plasma Focus Device Operated With Neon as a Copious Soft X-Ray Source
2017
[22] Numerical Experiments to Study the Variation of Pressure on India Bhabha Atomic Research Centre Plasma Focus
2017
[23] Numerical Experiments Performed on the Imperial College Plasma Focus Machine: Dependence on Deuterium Pressure
2016
[24] A 109 neutrons/pulse transportable pulsed DD neutron source based on flexible head plasma focus unit
Review of Scientific Instruments, 2016
[25] Measurement of Radiative Collapse in 2.2 kJ PF: Achieving High Energy Density (HED) Conditions in a Small Plasma Focus
Journal of Fusion Energy, 2016
[26] Comparative Study of Fast and Slow Focus Modes in INTI Plasma Focus for Deuterium, Neon and Argon Operation
Transactions on Plasma Science, 2016
[27] Seeding the m= 0 instability in dense plasma focus Z-pinches with a hollow anode
2016
[28] Gas Phase Switching for Pulsed Power Applications
2016
[29] X-ray Lithography of SU8 Photoresist using Fast Miniature Plasma Focus Device and its characterization using FTIR spectroscopy
Physics Letters A, 2015
[30] Comparison of Measured Soft X-Ray Yield Versus Pressure for NX1 and NX2 Plasma Focus Devices Against Computed Values Using Lee Model Code
Journal of Fusion Energy, 2015
[31] Neutron energy distribution and temporal correlations with hard x-ray emission from a hundreds of joules plasma focus device
Plasma Physics and Controlled Fusion, 2015
[32] Effects of Approximation and Close-Fitting Technique of Corona Model on Neon Soft X-Ray Emission in 3-kJ Plasma Focus
2015
[33] A DENSE PLASMA FOCUS DEVICE AS A PULSED NEUTRON SOURCE FOR MATERIAL IDENTIFICATION
2015
[34] Neutron Yield Scaling With Inductance in Plasma Focus
Plasma Science, IEEE Transactions on, 2015
[35] Dynamics of two microscale DPF devices
Journal of Physics D: Applied Physics, 2015
[36] Conditions for Radiative Cooling and Collapse in the Plasma Focus Illustrated With Numerical Experiments on PF1000
2015
[37] Results of Ultracompact Plasma Focus Operating in Repetitive Burst-Mode
Plasma Science, IEEE Transactions on, 2015
[38] Plasma Kinetics in Deuterium-Filled Plasma Focus with Step Anode Configuration
Journal of Computational and Theoretical Nanoscience, 2015
[39] Comparative study of plasma focus machines
2015
[40] Comparison of Measured Neutron Yield Versus Pressure Curves for FMPF-3, NX2 and NX3 Plasma Focus Machines Against Computed Results Using the Lee Model Code
Journal of Fusion Energy, 2014
[41] Influence of Kr doping on neon soft X-rays emission in fast miniature plasma focus device
Physics Letters A, 2014
[42] Developing a plasma focus research training system for the fusion energy age
International Journal of Modern Physics: Conference Series, 2014
[43] Numerical Study of Z-pinch Dynamics at Different Working Regimes
Journal of fusion energy, Springer, 2014
[44] Numerical experimentation on focusing time and neutron yield in GN1 plasma focus machine
International Journal of Modern Physics: Conference Series. Vol. 32. The Authors, 2014., 2014
[45] Plasma Focus Radiative Model: Review of the Lee Model Code
Journal of Fusion Energy, 2014
[46] Plasma focus ion beam-scaling laws
?International Journal of Modern Physics: Conference Series. Vol. 32. 2014., 2014
[47] Investigation of the Plasma Behavior in Filippov-Type Plasma Focus Using the State Space of Sing Lee's Model
Journal of Fusion Energy, Springer, 2014
[48] Properties of Ion Beams Generated by Nitrogen Plasma Focus
Journal of Fusion Energy, Springer, 2014
[49] Potential medical applications of the plasma focus in the radioisotope production for PET imaging
Physics Letters A, Elsevier, 2014
[50] NUMERICAL EXPERIMENTS TO OBTAIN THE SCALING LAWS FOR NEUTRON YIELD ON MATHER-TYPE PLASMA FOCUS MACHINES BELOW 500 JOULES
2014
[51] Some Generalised Characteristics of the Electro-dynamics of the Plasma Focus in Its Axial Phase: Illustrated by an Application to Independantly Determine the Drive Current Fraction and the Mass Swept-Up Fraction
Journal of Fusion Energy, 2014
[52] Numerical Experiments on PF1000 Neutron Yield
Journal of Fusion Energy, 2014
[53] Some generalised characteristics of the electro-dynamics of the plasma focus in its axial phase: Illustrated by an application to independantly determine the drive …
Journal of Fusion Energy, 2014
[54] INTI International University, 71800 Nilai, Malaysia. 2 Institute for Plasma Focus Studies, 32 Oakpark Drive, Chadstone, 3148 Australia. 3 Physics …
2013
[55] The Plasma Focus Numerical Experiments Leading Technology
2013
[56] Concrete shielding of neutron radiations of plasma focus and dose examination by FLUKA
2013
[57] Numerical Experiments of Ion Beams from Plasma Focus
SH Saw, S Lee - plasmafocus.net, 2013
[58] The Effect of Specific Heat Ratio on Neutron Yield
2013
[59] Plasma focus ion beam fluence and flux—for various gases
Journal of fusion energy, Springer, 2013
[60] Soft X-ray Emission Optimization Studies with Krypton and Xenon Gases in Plasma Focus Using Lee Model
Journal of Fusion Energy, 2013
[61] The plasma focus-numerical experiments leading technology
2013
[62] Numerical Experiments on Oxygen Plasma Focus: Scaling Laws of Soft X-Ray Yields
Journal of fusion energy, Springer, 2013
[63] Scaling Laws of Nitrogen Soft X-ray Yields from 1 to 200 kJ Plasma Focus
Journal of Fusion Energy, 2013
[64] Computational Study of Emitted Spectra from the Neon Plasma Focus
Journal of Fusion Energy, 2013
[65] Optimization of neon soft X-rays emission from 200 J fast miniature dense plasma focus device: A potential source for soft X-ray
Physics Letters A, Elsevier, 2013
[66] Numerical experiments on plasma focus for soft x-ray yield scaling laws derivation using Lee model
2012
[67] The plasma focus—trending into the future
International Journal of Energy Research, 2012
[68] Statistical characterization of the reproducibility of neutron emission of small plasma focus devices
Physics of Plasmas (1994-present), 2012
[69] Plasma focus ion beam fluence and flux—scaling with stored energy
Physics of Plasmas (1994-present), 2012
[70] Dependence of plasma focus argon soft x-ray yield on storage energy, total and pinch currents
Journal of fusion energy, Springer, 2012
[71] Numerical experiments in plasma focus operated in various gases
Plasma Science, IEEE Transactions on?, 2012
[72] Current-step technique to enhance plasma focus compression and neutron yield
Journal of fusion energy, Springer, 2012
[73] Numerical Experiments Providing New Insights into Plasma Focus Fusion Devices
Energies, 2010
[74] Joint ICTP-IAEA Workshop on Dense Magnetized Plasma and Plasma Diagnostics
2010
[75] " INTI University College, 71800 Nilai, Malaysia* Institute for Plasma Focus Studies, 32 Oakpark Drive, Chadstone, VIC3148, Australia" Nanyang Technological …
Follow SCIRP
Twitter Facebook Linkedin Weibo
Contact us
+1 323-425-8868
customer@scirp.org
WhatsApp +86 18163351462(WhatsApp)
Click here to send a message to me 1655362766
Paper Publishing WeChat
Free SCIRP Newsletters
Copyright © 2006-2024 Scientific Research Publishing Inc. All Rights Reserved.
Top