Laser Magnetized Plasma Interactions for the Creation of Solid Density Warm (~200 eV) Matter M.S. R. Presura, Y. Sentoku, A. Kemp, C. Plechaty,

Slides:

Advertisements

Similar presentations

Control of Magnetic Chaos & Self-Organization John Sarff for MST Group CMSO General Meeting Madison, WI August 4-6, 2004.

Advertisements

Anomalous Ion Heating Status and Research Plan

Electron transport in the shock ignition regime Tony Bell University of Oxford Rutherford Appleton Laboratory Acknowledgements: Guy Schurtz, Xavier Ribeyre.

Slide 1 Refraction of Light. Slide 2 Wave Boundary Behavior wave speed and wavelength are greater in less dense medium wave frequency is not altered by.

The Reversed Field Pinch: on the path to fusion energy S.C. Prager September, 2006 FPA Symposium.

427 PHC.  Atomic emission spectroscopy (AES) is based upon emission of electromagnetic radiation by atoms.

1 Introduction to Plasma Immersion Ion Implantation Technologies Emmanuel Wirth.

Nuclear Physics Year 13 Option 2006 Part 2 – Nuclear Fusion.

HEDLP FESAC Subpanel Workshop August, 2008 Nevada Terawatt Facility, University of Nevada Reno Joseph M. Kindel Nevada Terawatt Facility College of Science.

Astronomy190 - Topics in Astronomy

Chapter 29 Continued-Chapter 31- Chapter EMF Induced in a Moving Conductor Example 29-8: Force on the rod. To make the rod move to the right.

Physics of fusion power Lecture 11: Diagnostics / heating.

Post Main Sequence Evolution PHYS390 (Astrophysics) Professor Lee Carkner Lecture 15.

Fast Ignition Fast Ignition: Some Issues in Electron Transport Some fundamentals of large currents moving through dense materials Some unexpected problems.

Diagnostics for Benchmarking Experiments L. Van Woerkom The Ohio State University University of California, San Diego Center for Energy Research 3rd MEETING.

Modeling the benchmark experiments Mingsheng Wei, Fei He, John Pasley, Farhat Beg,… University of California, San Diego Richard Stephens General Atomics.

Simulations of Neutralized Drift Compression D. R. Welch, D. V. Rose Mission Research Corporation Albuquerque, NM S. S. Yu Lawrence Berkeley National.

Aerosol protection of laser optics by Electrostatic Fields (not manetic) L. Bromberg ARIES Meeting Madison WI April 23, 2002.

Plasma Dynamics Lab HIBP Abstract Measurements of the radial equilibrium potential profiles have been successfully obtained with a Heavy Ion Beam Probe.

Physics of fusion power Lecture 8 : The tokamak continued.

Study of D-D Reaction at the Plasma Focus Device P. Kubes, J. Kravarik, D. Klir, K. Rezac, E. Litseva, M. Scholz, M. Paduch, K. Tomaszewski, I. Ivanova-Stanik,

Power of the Sun. Conditions at the Sun’s core are extreme –temperature is 15.6 million Kelvin –pressure is 250 billion atmospheres The Sun’s energy out.

Assembly of Targets for RPA by Compression Waves A.P.L.Robinson Plasma Physics Group, Central Laser Facility, STFC Rutherford-Appleton Lab.

Chamber Clearing by Electrostatic Fields L. Bromberg ARIES Meeting UCSD January 10, 2002.

Physics 1051 Lecture 6/7 Slide 1 Refraction of Light.

Photoelectron Spectroscopy Lecture 7 – instrumental details –Photon sources –Experimental resolution and sensitivity –Electron kinetic energy and resolution.

Alexander Brandl ERHS 630 Exposure and Dose Environmental and Radiological Health Sciences.

Physics of fusion power Lecture 2: Lawson criterion / Approaches to fusion.

Measurement of Magnetic field in intense laser-matter interaction via Relativistic electron deflectometry Osaka University *N. Nakanii, H. Habara, K. A.

Physics of Fusion power Lecture4 : Quasi-neutrality Force on the plasma.

ECE/ChE 4752: Microelectronics Processing Laboratory

Atomic Emission Spectroscopy

Chapter 5 Diffusion and resistivity

Chapter 10 Physics of Highly Compressed Matter. 9.1 Equation of State of Matter in High Pressure.

Great feeling Walking Ifen without machines Sunday Jan 26, 2007.

P5 – Electric Circuits. Static Electricity When two objects are rubbed together and become charged, electrons are transferred from one object to the other.

Electron interactions with CO 2 Bob Merlino Department of Physics and Astronomy The University of Iowa Iowa City, IA U. S. Department of Energy National.

Initial wave-field measurements in the Material Diagnostic Facility (MDF) Introduction : The Plasma Research Laboratory at the Australian National University.

40 Nuclear Fission and Fusion After fusion, the total mass of the light nuclei formed in the fusion process is less than the total mass of the nuclei that.

Tools for Nuclear & Particle Physics Experimental Background.

Highlights of talk : 1.e+e- pair laser production 1.Collisionless shocks 1.Colliding laser pulses accelerator.

LCLS Plasma and Warm Dense Matter Studies Richard W. Lee, Lawrence Livermore National Laboratory P. Audebert, Laboratoire pour l’Utilisation des Lasers.

Components of the Rubidium Apparatus Magnet: Confines the electron beam to go through the aperture separating the source and target chambers. Probe Laser:

Obtaining Ion and Electron Beams From a source of Laser-Cooled Atoms Alexa Parker, Gosforth Academy  Project Supervisor: Dr Kevin Weatherill Department.

Plasmas. The “Fourth State” of the Matter The matter in “ordinary” conditions presents itself in three fundamental states of aggregation: solid, liquid.

International Symposium on Heavy Ion Inertial Fusion June 2004 Plasma Physics Laboratory, Princeton University “Stopping.

Electromagnetic Waves and Their Propagation Through the Atmosphere

M. Ichimura, Y. Yamaguchi, R. Ikezoe, Y. Imai, T. Murakami,

LSP modeling of the electron beam propagation in the nail/wire targets Mingsheng Wei, Andrey Solodov, John Pasley, Farhat Beg and Richard Stephens Center.

Lesson 29 Wave Characteristics of Light. Wave Function for Light v=λν i.For light v = 3.0x108m/s according to Einstein (maybe false now????)

18.1b Notes States of Matter & Phase Changes Supplement to Chapter 18.

EXAM II Monday Oct 19 th (this coming Monday!) HW5 due Friday midnight.

N is the electron density (in this case produced by intense heating in the lightning channel) e is the charge of an electron (-1.6 x C) m is the.

The FAIR* Project *Facility for Antiproton and Ion Research Outline:  FAIR layout  Research programs Peter Senger, GSI USTC Hefei Nov. 21, 2006 and CCNU.

Transport in three-dimensional magnetic field: examples from JT-60U and LHD Katsumi Ida and LHD experiment group and JT-60 group 14th IEA-RFP Workshop.

A Basic Introduction & Some Cool Stuff

-Plasma can be produced when a laser ionizes gas molecules in a medium -Normally, ordinary gases are transparent to electromagnetic radiation. Why then.

UNR activities in FSC Y. Sentoku and T. E. Cowan $40K from FSC to support a graduate student, Brian Chrisman, “Numerical modeling of fast ignition physics”.

R Wyllie, R Wakai, T G Walker University of Wisconsin, Madison Spin-Exchange Relaxation Free Heart signal frequency spectrum from DC-100Hz Adult heart.

Fyzika tokamaků1: Úvod, opakování1 Tokamak Physics Jan Mlynář 6. Neoclassical particle and heat transport Random walk model, diffusion coefficient, particle.

Large Area Plasma Processing System (LAPPS) R. F. Fernsler, W. M. Manheimer, R. A. Meger, D. P. Murphy, D. Leonhardt, R. E. Pechacek, S. G. Walton and.

INTERACTIONS OF RADIATION WITH MATTER. twCshttp:// twCs

Trident Laser Facility

Munib Amin Institute for Laser and Plasma Physics Heinrich Heine University Düsseldorf Laser ion acceleration and applications A bouquet of flowers.

Time-Resolved X-ray Absorption Spectroscopy of Warm Dense Matter J.W. Lee 1,2,6, L.J. Bae 1,2, K. Engelhorn 3, B. Barbel 3, P. Heimann 4, Y. Ping 5, A.

Physical Mechanism of the Transverse Instability in the Radiation Pressure Ion Acceleration Process Yang Wan Department of Engineering Physics, Tsinghua.

Features of Divertor Plasmas in W7-AS

1.6 Glow Discharges and Plasma

M. Povarnitsyn, K. Khishchenko, P. Levashov

Components of the Rubidium Apparatus

Presentation transcript:

Laser Magnetized Plasma Interactions for the Creation of Solid Density Warm (~200 eV) Matter M.S. R. Presura, Y. Sentoku, A. Kemp, C. Plechaty, D. Martinez, T.E. Cowan Nevada Terrawatt Facility, University of Nevada Reno, Reno NV I. ABSTRACT VII. ATOMIC NUMBER AND ION Ultra-intense lasers are the principal tools currently used in the production of short lived high energy density plasmas. The formation of solid density plasmas with temperatures of a few hundred eV by laser irradiation is hampered by the rapid diffusion of hot electrons throughout the target volume. The use of an ultra-high magnetic field to contain radial diffusion while isochorically heating a dense target for a picosecond with a laser, presents the possibility of creating a fundamentally new plasma regime in the laboratory to study HED physics, including ionization processes and opacities relevant to fusion and astrophysics. Moreover, the comprehensive understanding of hot electron transport in a dense plasma in the presence of strong external magnetic fields could open the prospect of Magnetized Fast Ignition to better couple PW laser energy into a magnetized compressed fuel core. III. MAGNETIC FIELD GENERATION Our magnetic field is produced using the 1MA Zebra pulsed power generator. The current is passed through either a single/double turn helix, or a single/multi wire horse shoe coil. II. HOT ELECTRON CONFINEMENT In the absence of a magnetic field the hot electrons are confined inside the target by the electrostatic sheath fields excited at the target surface, but the electrons are not confined radially, and therefore they diffuse away from the focal region. In the presence of a magnetic field the hot electrons are confined inside the target not only by the electrostatic sheath fields excited at the target surface, but also by the axial magnetic field which acts by reducing the mean free path of the electrons. This slows down the radial diffusion long enough for the electrons to couple with the ions and heat the target. IV. MAGNETIC FIELD MEASUREMENTS Magnetic field measurements are made using a 532 nm laser and a Faraday probe. A magnetic field will create an anisotropy in the glass and change the indices of refraction for right and left circularly polarized light.. The polarization of laser light incident on the Faraday probe is compared to the polarization of the light exiting the Faraday probe in order to determine the magnitude of the magnetic field inside the probe. Due to the balance between the increased cold electron to hot electron coupling for high Z materials, and the increased energy loss for high Z materials due to bremsstrahlung, there exists an optimum range of materials suitable for picosecond ion heating. Note that this model does not include incomplete ionization or diffusion, and is optically thin. If the cold electrons are anomalously heated by the Weibel instability to a temperature proportional to 1/Z (1keV/Z in this model) the optimum range for picosecond ion heating is in the low Z range. VI. ELECTRON-ION COUPLING The three specie’s (cold electrons, hot electrons, and ions) temperature equilibration is calculated using a Spitzer-Eidmann hybrid collision frequency model. The hot electrons are found to couple with the cold electrons which then couple with the ions. The hot electrons are found to not heat the ions significantly. V. ENERGY COUPLING BETWEEN SPECIES