The%20UW%20Plasma%20Physics%20Group - PowerPoint PPT Presentation

About This Presentation

Title:

The%20UW%20Plasma%20Physics%20Group

Description:

Fundamental plasma physics. The RFP as a fusion concept. Fundamental plasma physics in common with astrophysics. Magnetic self-organization MST ... – PowerPoint PPT presentation

Number of Views:86

Avg rating:3.0/5.0

Slides: 20

Provided by: JCSp

Learn more at: https://sprott.physics.wisc.edu

Category:

more less

Transcript and Presenter's Notes

Title: The%20UW%20Plasma%20Physics%20Group

1
The UW Plasma Physics Group

Clint Sprott, Paul Terry, Ellen Zweibel, Stas
Boldyrev, Dalton Schnack, Cary Forest, Stewart
Prager
Presented to
Introductory Seminar for New Graduate Students
on September 6, 2007

2
Plasma Physics

What is a Plasma?
Ionized gas (kT gt a few eV)
The fourth state of matter
99 of the universe
History of Plasma Physics
1920s - Langmuir (vacuum tubes)
1930s - Appleton (ionosphere)
1950s - Nuclear Fusion
1960s - Solar wind, stellar interiors
1980s - Industrial applications

3
Wisconsin Plasma Physics Program

Began in 1962 by Donald W. Kerst
Present Physics Faculty
Clint Sprott (computational dynamics)
Paul Terry (theory)
Ellen Zweibel - joint with Astronomy (theory)
Stas Boldyrev (theory)
Dalton Schnack part-time (computational)
Cary Forest (experimental)
Stewart Prager (experimental)
Plasma Research in other UW Departments
Stellarator/Torsatron (ECE)
Spherical Tokamak (EP)
Fusion Technology Institute (EP)
Plasma Theory Computation (EP)
Plasma Processing (EP)

4
Plasma Physics Group

Composition
7 faculty
11 scientists
9 postdocs
28 graduate students
27 support staff
frequent and long-term visitors
gt 80 people total
Funding (8M year)
80 Ph.D. graduates over 40 years
50 at National Labs
25 at Universities
25 in Industry
http//plasma.physics.wisc.edu/

5
Nuclear Fusion

D T ? 4He (3.5 MeV) n (14 MeV)
Inexhaustible Source of Energy
D2 in oceans will last 3 x 108 years
1 gal H2) 1/8 g D2 300 gal gasoline
Must contain DT plasma _at_ kT gt 10 keV for n? gt
1020 sec/m3 (Coulomb barrier)
Scientific Feasibility Essentially Proven
Much Work Remains
Physics
Technology

6
What to do if Interested

Come around and get Acquainted
Take Plasma Courses
525 introduction
526 plasma lab (EP)
527 confinement devices
528 plasma processing
724 waves instabilities
725 plasma kinetic theory
726 magnetohydrodynamics
Plasma Seminar 1205 Mon (1227 Engr)
Group Meeting 400 Thurs (5280 Ch)
Summer Jobs Available
Pass Qualifiers

7
Paul Terry
8
(No Transcript)
9
Turbulence in fusion and astrophysics

Interests (organizing principles)
Physics of coherent structure formation in
turbulence
Role of symmetry-breaking waves
Role of strongly inhomogeneous background
(e.g., shear flow)
Applications
Transport in fusion plasmas
Interstellar medium

10
(No Transcript)
11
Ellen Zweibel
12
(No Transcript)
13
(No Transcript)
14
Stas Boldyrev
15
Why to Study Plasma Physics?
Controlled fusion practically infinite source
of energy!
Almost all Galactic volume and Universe volume
are filled with a plasma!
It is just fun astrophysical plasma flows
exhibit regimes that have never been
investigated in terrestrial experiments!
16
What is special about plasma?

Very hot, ionized gas.
How to confine it?
Plasma consists of electrons and ions weakly
interacting with each other. Can sustain currents
-gt can interact with magnetic fields.

17
Plasma in Magnetic Field
Magnetized plasma is usually unstable and
turbulent
Good confiment
18
Plasma Turbulence
Solar wind
MST, UW-Madison
19
Plasma Turbulence
Interstellar medium
20
Plasma Turbulence

One of the main topics of our theoretical group.
Goals
Explain turbulence in MST experiment
turbulence in the Solar wind
turbulence in the Interstellar Medium

21
Dalton Schnack

Computational Physics
Fluid models of plasmas
Plasmas in astrophysics

22
Research Interests

Magnetohydrodynamics (MHD)
Extended MHD (2-fluid/FLR effects)
Fluid models for tokamak plasmas (closures)
Plasma relaxation/dynamo
Large scale computations for fluid plasmas
MHD/RF interactions
Anomalous angular momentum transport in
magnetized plasmas
Structure and heating of the solar corona
Accretion disk coronae

23
Cary Forest
24
(No Transcript)
25
(No Transcript)
26
The MST Experiment(Madison Symmetric Torus)
a reversed field pinch (RFP)
27
MST
minor radius 0.5m current lt 0.5 kA, T 107 k,
n 1013 cm-3
28
The confining magnetic field is weak

Plasma is relatively unstable an advantage for
fusion energy
Magnetic fluctuations are large need to reduce
energy loss
Energy is lost rapidly

29
The purpose of MST research

Fundamental plasma physics
The RFP as a fusion concept
Fundamental plasma physics in common with
astrophysics

30
Magnetic self-organization MST
magnetic fluctuations
toroidal magnetic flux
dynamo
heat flux (MW/m2)
energy transport
rotation (km/s)
momentum transport
ion temperature (keV)
ion heating
time (ms)
31

for fusion energy
learn to suppress magnetic self-organization
for astrophysics
understand magnetic self-organization common
to lab and cosmos

32
Plasma properties measured with

Lasers
Neutral atom beams
Ion beams
Spectroscopy
and more

33
plasma controlled with

EM waves
Induced electric fields
Neutral beams

34
Graduate student research on MST

MST is a team effort with strong scientific and
technical interactions very dynamic
Many mentors available for graduate students
Each student owns a physics problem
Many physics and instrumentation opportunities

35
Stewart Prager
36
The NSF Center for Magnetic Self-Organization in
Laboratory and Astrophysical Plasmas