Post on 01-Apr-2015
Siam Physics Congress SPC2013Thai Physics Society on the Road to ASEAN Community 21-23 March 2013
From Electric Birth through Micro-nova to
Streaming Demise of the Plasma Focus-
Knowledge and Applications
S Lee1,2,3 & S H Saw1,2
1INTI International University, 71800 Nilai, Malaysia
2Institute for Plasma Focus Studies, Chadstone, VIC 3148, Australia3University of Malaya, Kuala Lumpur, Malaysia
e-mail:; leesing@optusnet.com.au; sorheoh.saw@newinti.edu.my
Introductory: What is a Plasma?
Four States of Matter
SolidLiquidaseousPlasma
Four States of Matter SOLID LIQUID GAS PLASMA
Matter heated to high temperatures
becomes a Plasma
One method: electrical discharge
through gases.
Lightning: Electric discharge (e.g. 20kA) between earth & clouds heats up the air in the discharge channels to high temperatures (30,000 K) producing air plasmas
Current I & self-field B produces force JXB pointing everywhere radially inwards-
Pinches column from initial radius r0 to final radius rm.
Pinching Process
• Dynamic pinching process requires current to rise very rapidly, typically in under 0.1 microsec in order to have a sufficiently hot and dense pinch.
• Super-fast, super-dense pinch; requires special MA fast-rise (nanosec) pulsed-lines; Disadvantages: conversion losses & cost of high technology pulse-shaping line, additional to the capacitor.
Superior method for super-dense-hot pinch: plasma focus (PF)
• The PF produces superior densities and temperatures. (easily a million C up to tens of millions C)
• 2-Phase mechanism of plasma production does away with the extra layer of technology required by fast pinches
• A simple capacitor discharge is sufficient to power the plasma focus.
High Power Radiation from PF
• Powerful bursts of x-rays, ion & electron beams, & EM radiation (>10 gigaW)
• Intense radiation burst, extremely high powers
• E.g. SXR emission peaks at 109 W over ns
• In deuterium, fusion neutrons also emitted
INTI PF- 3 kJ Plasma Focus
1m
The Plasma Dynamics in FocusThe Plasma Dynamics in Focus
HV 30 F, 15 kV
Inverse Pinch Phase
Axial Accelaration Phase
Radial Phase
1972: UM plasma focus discharge in Two Asian Firsts up to that time:Achieved 1.9 MA pulsed dischargeDetected and measured Plasma D-D fusion neutrons-
Today- PF Collaboration among ASEAN InstitutionsThailand: Chulalongkorn University.. Thammasat University: Prince of Songla U
PF Applications : e.g. PF Isotope production PF development
Enhancing Polypropylene-polyester/ for medical applications
Cotton Composites Lamination
Rattachat, Mongkolnavin, et al
Singapore: PF Radiation:
NTU/NIE
Malaysia: INTI IU- IPFS
U Malaya : PF Studies PF Numerical Expts
UTM
PF Applications e.g. Nano-materials;
Radiative Cooling & Collapse
Photo of the INTI PF pinch (P Lee) using filter technique to show the pinch region & the jet
Shadowgraphs of PF Pinch- (Micro-nova)M Shahid Rafique PhD Thesis NTU/NIE Singapore 2000
• Highest post-pinch axial shock waves speed ~50cm/us M500
• Highest pre-pinch radial speed>25cm/us M250
Much later…Sequence of shadowgraphicsof post-pinch copper jet
S Lee et al J Fiz Mal 6, 33 (1985)
• Slow Copper plasma jet 2cm/us M20
Emissions from the PF Pinch region
The ion beams, plasma streams and anode-sputtered jets are used for
advanced materials modification and fabrication, including nano-materials; and for studies of materials damage
+Mach500 Plasma stream
+Mach20 anode material jet
3 kJ machine
Small Plasma Focus 1000 kJ chamber only
Big Plasma Focus
1 m
Comparing large & small PF’s- Dimensions & lifetimes- putting shadowgraphs of pinch side-by-side, same scale
Lifetime ~10ns order of ~200 ns
Anode radius 1 cm 11.6 cm
Pinch Radius: 1mm 12mm
Pinch length: 8mm 90mm
Comparison (Scaling) - 1/2 Important machine properties:
UNU ICTP PFF PF1000
E0 3kJ at 15 kV 600kJ at 30kV
I0 170 kA 2MA
‘a’ 1 cm 11.6 cm
Comparison (Scaling) - 2/2Important Compressed Plasma Properties
• Density of plasma- same!!
• Temperature of plasma same!! These two properties determine radiation intensity
energy radiated per unit volume per unit lifetime of plasma)
• Size of plasma
• Lifetime of plasma These two properties together with the above two
determine total yield.
Basic information from simple measurements
• Speed is easily measured; e.g
• From current waveform
16 cm traversed in 2.7 us
Av speed=6 cm/us
Form factor= 1.6
Peak speed ~ 10 cm/us
At end of axial phase
Estimate Temperature from speeds
• Speed gives KE.
• Shock Waves convert half of KE to Thermal Energy:
• T~q2 ; where q is the shock speed ~ speed of current sheet.
• For D2: T=2.3x10-5q2 K q in m/s
(from strong shock-jump conservation equations)
Compare Temperatures: speeds easily measured; simply from a current waveform; from speeds, temperature may be computed.
UNU ICTP PFF PF1000 D2
Axial speed 10 [measured] 12 cm/us
Radial speed 25 20 cm/us
Temperature 1.5x106 1x106 K
Reflected S 3x106 2x106 KAfter RS comes pinch phase which may increase T a little more in each case
Comparative T: about same; several million K
Compare Number Density – 1/2• During shock propagation phase, density is controlled by
the initial density and by the shock-’jump’ density• Shock density ratio=4 (for high temperature deuterium)• RS density ratio=3 times• On-axis density ratio=12• Initial at 3 torr n=2x1023 atoms m-3
• RS density ni=2.4x1024 m-3 or 2.4x1018 per cc
• Further compression at pinch; raises number density higher
typically to 1019 per cc.
Compare Number Density – 2/2
• Big or small PF: initial density small range of several torr
• Similar shock processes
• Similar final density
Big PF and small PFSame density, same temperature
• Over a range of PFs smallest 0.1J to largest 1 MJ; over the remarkable range of 7 orders of magnitude- same initial pressure, same speeds
• Conclusion: all PF’s:• Same T, hence same energy (density) per unit mass
• same n, hence same energy (density) per unit volume
• Hence same radiation intensity
Next question: How does yield vary?
• Yield is Intensity x Volume x Lifetime
Yield~ radius4
Or ~ current4
Our research towards applicationsSome plasma focus applications experimented with to
various levels of success. • Microelectronics lithography towards nano-scale using
focus SXR, EUV and electrons• Micro-machining• Surface modification and alloying, deposition of
advanced materials: superconducting films, fullerenes, DLC films, TiN, ZrAlON, nanostructured magnetic e.g. CoPt thin films
• Surface damage for materials testing in high-radiation and energy flux environment
Applications list/2
Diagnostic systems of commercial/industrial value: • CCD-based imaging• multi-frame ns laser shadowgraphy• pin-hole and aperture coded imaging systems• neutron detectors, neutron activation, gamma ray
spectroscopy • diamond and diode x-ray spectrometer• vacuum uv spectrometer• Faraday cups• mega-amp current measurement• pulsed magnetic field measurement• templated SXR spectrometry• water-window radiation for biological applications
Applications list/3
Pulsed power technology:• capacitor discharge• Pulsed power for plasma, optical and lighting systems • triggering technology • repetitive systems • circuit manipulation technology such as current-steps
for enhancing performance and compressions• powerful multi-radiation sources with applications
in materials and medical applications
Applications list/4
• Plasma focus design; complete package integrating hardware, diagnostics and software.
• Fusion technology and fusion education, related to plasma focus training courses
Applications: SXR Lithography
• As linewidths in microelectronics reduces towards 0.1 microns, SXR Lithography is set to replace optical lithography.
• Baseline requirements, point SXR source– less than 1 mm source diameter– wavelength range of 0.8-1.4 nm – from industrial throughput considerations,
output powers in excess of 1 kW (into 4)
Applications:
some ‘products’
1. 300J portable (25 kg); 106 neutrons per shot fusion device
2. SXR lithography using NX2 in neon
8 9 10 11 12 13 140.0
0.2
0.4
0.6
0.8
1.0
ba
9 8
2
34
567
1
inten
sity
(a.u.
)
wavelength (Å)
Lines transferred using NX2 SXR
SEM Pictures of transfers in AZPN114 using NX2 SXR
X-ray masks in Ni & Au
3. X-ray Micromachining
4. Thin film deposition, fabrication
Materials modification using Plasma Focus Ion Beam
For plasma processing of thin film materials on different substrates with different phase changes.
Applications: depositing Chromium and TiN- M Ghoranneviss
5. Applications: Nanoparticles synthesis R S Rawat et al
• Synthesize nano-phase (nano-particles,nano-clusters and nano-composites) magneticmaterials
• mechanism of nano-phase material synthesis
• effect of various deposition parameters on themorphology and size distribution of deposited nano-phase material
• To reduce the phase transition temperatures
Applications for nano-particles
• DataStorage
• Medical Imaging
• Drug Delivery
• Cancel Therapy
100nm FeCo agglomerates deposited
NX2 set-up for depositing thin films; deposited thin films with consisting of 20nm particles
6. Developing the most powerful training and research system for the dawning of the Fusion Age.
Integrate:
• the proven most effective hardware system of the UNU/ICTP PFF with
• the proven most effective numerical experiment system Lee Model code
with emphasis on dynamics, radiation and materials applications.
6a. The proven most effective 3 kJ PF system.
The trolley based UNU/ICTP PFF 3 kJ plasma focus training and research system will be updated as a 1 kJ system
6b. The proven most effective and comprehensive Model code
• Firmly grounded in Physics
• Connected to reality
• From birth to death of the PF
• Useful and comprehensive outputs
• Diagnostic reference-many properties, design, scaling & scaling laws, insights & innovations
Our Radiative Plasma Focus Code
6c. The proven tradition and spirit of collaboration
Conclusion
• What is a plasma?
• Plasma focus and its pinch
• The Pinch and the streaming death
• Radiation products of the PF pinch
• Research on some applications- showing ‘products’ as achieved (varying stages) and visualised
THANK YOU
Simple
Profound
Plasma Focus