Author: J. Edwards
Publisher:
ISBN:
Category :
Languages : en
Pages : 6
Book Description
An electromagnetic solenoid was developed to study the quenching of nonlocal heat transport in laser-produced gas-jet plasmas by high external magnetic fields. The solenoid, which is driven by a pulsed power system supplying 30 kJ, achieves fields exceeding 10 T. Temporally resolved measurements of the electron temperature profile transverse to a high power laser beam were obtained using Thomson Scattering. A method for optimizing the solenoid design based on the available stored energy is presented.
Development and Characterization of a High Magnetic Field Solenoid for Laser Plasma Experiments
Author: J. Edwards
Publisher:
ISBN:
Category :
Languages : en
Pages : 6
Book Description
An electromagnetic solenoid was developed to study the quenching of nonlocal heat transport in laser-produced gas-jet plasmas by high external magnetic fields. The solenoid, which is driven by a pulsed power system supplying 30 kJ, achieves fields exceeding 10 T. Temporally resolved measurements of the electron temperature profile transverse to a high power laser beam were obtained using Thomson Scattering. A method for optimizing the solenoid design based on the available stored energy is presented.
Publisher:
ISBN:
Category :
Languages : en
Pages : 6
Book Description
An electromagnetic solenoid was developed to study the quenching of nonlocal heat transport in laser-produced gas-jet plasmas by high external magnetic fields. The solenoid, which is driven by a pulsed power system supplying 30 kJ, achieves fields exceeding 10 T. Temporally resolved measurements of the electron temperature profile transverse to a high power laser beam were obtained using Thomson Scattering. A method for optimizing the solenoid design based on the available stored energy is presented.
High Magnetic Field Generation for Laser-plasma Experiments
Author: J. S. Ross
Publisher:
ISBN:
Category :
Languages : en
Pages : 8
Book Description
An electromagnetic solenoid was developed to study the effect of magnetic fields on electron thermal transport in laser plasmas. The solenoid, which is driven by a pulsed power system suppling 30 kJ, achieves magnetic fields of 13 T. The field strength was measured on the solenoid axis with a magnetic probe and optical Zeeman splitting. The measurements agree well with analytical estimates. A method for optimizing the solenoid design to achieve magnetic fields exceeding 20 T is presented.
Publisher:
ISBN:
Category :
Languages : en
Pages : 8
Book Description
An electromagnetic solenoid was developed to study the effect of magnetic fields on electron thermal transport in laser plasmas. The solenoid, which is driven by a pulsed power system suppling 30 kJ, achieves magnetic fields of 13 T. The field strength was measured on the solenoid axis with a magnetic probe and optical Zeeman splitting. The measurements agree well with analytical estimates. A method for optimizing the solenoid design to achieve magnetic fields exceeding 20 T is presented.
Development and Characterization of the Magnetic Plasmatron
Author: Felipe Rene Anziani
Publisher:
ISBN:
Category :
Languages : en
Pages : 164
Book Description
The purpose of this thesis is to investigate the plausibility of developing a low current plasmatron fuel reformer that utilizes magnetic fields to hydrodynamically induce spin of the arc discharge. The proof of principle, development, design, and characterization of the device are discussed. Important parameters for fuel reforming are determined. Comparisons are made between this device and other applications of this atmospheric glow discharge. After a thorough investigation, it has been determined that utilizing magnets to generate a mirror type magnetic field geometry can significantly improve the performance characteristics of the plasmatron. In addition, the effective dynamic range of the device can be increased dramatically by utilizing this magnetic field geometry.
Publisher:
ISBN:
Category :
Languages : en
Pages : 164
Book Description
The purpose of this thesis is to investigate the plausibility of developing a low current plasmatron fuel reformer that utilizes magnetic fields to hydrodynamically induce spin of the arc discharge. The proof of principle, development, design, and characterization of the device are discussed. Important parameters for fuel reforming are determined. Comparisons are made between this device and other applications of this atmospheric glow discharge. After a thorough investigation, it has been determined that utilizing magnets to generate a mirror type magnetic field geometry can significantly improve the performance characteristics of the plasmatron. In addition, the effective dynamic range of the device can be increased dramatically by utilizing this magnetic field geometry.
Scientific and Technical Aerospace Reports
Fusion Energy Update
Energy Research Abstracts
Nuclear Science Abstracts
U.S. Government Research Reports
Technical Abstract Bulletin
Author: Defense Documentation Center (U.S.)
Publisher:
ISBN:
Category : Science
Languages : en
Pages : 824
Book Description
Publisher:
ISBN:
Category : Science
Languages : en
Pages : 824
Book Description