Presentation is loading. Please wait.

Presentation is loading. Please wait.

Mach Cones in a 2D Dusty Plasma Crystal J. Goree Dept. of Physics and Astronomy, University of Iowa with results from V. Nosenko, Z. Ma, and D. Dubin Supported.

Published byMelvin Simmons Modified over 8 years ago

Similar presentations

Presentation on theme: "Mach Cones in a 2D Dusty Plasma Crystal J. Goree Dept. of Physics and Astronomy, University of Iowa with results from V. Nosenko, Z. Ma, and D. Dubin Supported."— Presentation transcript:

1 Mach Cones in a 2D Dusty Plasma Crystal J. Goree Dept. of Physics and Astronomy, University of Iowa with results from V. Nosenko, Z. Ma, and D. Dubin Supported by DOE, NASA, NSF

2 electrons + ions = plasma What is a dusty plasma? Debye shielding small particle of solid matter becomes negatively charged absorbs electrons and ions

3 – polymer microspheres –  8  m diameter Particles

4 Comparison of dusty plasma & pure ion plasmas Similar: repulsive particles Crystals & liquids 2D or 3D suspensions direct imaging laser-manipulation of particles Different - dusty plasma has: gaseous background 10 5  charge no inherent rotation gravity effects Yukawa potential

5 Gas drag Ion drag Thermophoresis  r 2 Forces Acting on a Particle Coulomb trapping potential inter-particle  r 1 Gravity  r 3

6 Electrostatic trapping of particles Equipotential contours electrode positive potential electrode With gravity, particles sediment to high-field region  2-D layer possible Without gravity, particles fill 3-D volume QE mg

7 chamber top-view camera laser illumination side-view camera vacuum chamber

8 Gas Ar, 15 mTorr RF plasma 13.56 MHz 20 W Polymer microspheres diameter 8.69  0.17  m Experimental conditions

9 charge Q  13000 e separation a = 762  46  m Lattice All experiments in this talk: a monolayer of particles  2D physics Triangular lattice with hexagonal symmetry

10 Pair correlation function  Ordered lattice Many peaks in g(r) Translation order length  9a

11 Compressional and shear waves

12 Dispersion relations in 2D triangular lattice

13 Mach cones (in air) courtesy of D. Dubin Shock wave behind an f-18

14 Mach cone angle  courtesy of D. Dubin C = U Sin   U

15 Lateral wake Transverse Wake Wake behind a ship courtesy of D. Dubin

16 Experimental setup scanning mirror

17 Data analysis method Trace particle orbits Calculate particle velocity, number density Get top view images of the lattice Determine particle positions

18 Laser manipulation of particles Ar laser beam 0.2 - 1 W motion of laser spot:  to radiation force direction shown here, || motion is also possible radiation force

19 Shear wave Mach cone V/C l = 0.51 V

20 Speed map for compressional Mach cone particle speed v (  m/s)

21 Lateral wake Transverse Wake Wake behind a ship courtesy of D. Dubin

22 speed map for compressional Mach cone particle speed v (  m/s)

23 V/C l = 2.23: compressional wave Mach cone Grey-scale speed map 2 mm Vector velocity map 2 mm  n  t Schlieren map 2 mm  v  vorticity map Big  n/  t  compressional waves small  v  not shear waves

24 V/C l = 0.51: shear wave Mach cone Grey-scale speed mapVector velocity map  n  t Schlieren map 2 mm  v  vorticity map small  n/  t  not compressional big  v  shear waves

25 Test of Mach cone angle relation C l = 22.1 mm/s C t = 5.8 mm/s

26 Comparison to MD simulation MD simulation by Z.W. MaExperiment 2 mm V/C l = 0.51

27 Compressional & Shear wave Mach cones Scanning parallel to radiation force direction, V/C l = 1.35 Shear wave Mach cone

28 Theory of wakes in a 2D plasma crystal Dubin, Phys. Plasmas 2000 Wakes with dispersion: c = c(k)   /k Wave equation Phase mixing  cancellation everywhere except where constructive interference occurs (loci of stationary phase)

29 V/C l > 1: Mach cone and lateral wakes color map experimental  n/  t Schlieren map no fitting parameter  = 1.14 V/C l = 1.21 calculation by Dubin Mach cone lateral

30 2 mm V/C l < 1: transverse wake transverse  = 1.14 V/C l = 0.51  n/  t Schlieren map

31 Summary Mach cones were observed in a 2D dusty plasma crystal Shear wave & Compressional Waves Compressional wave: Rich wake structure was observed for both supersonic and undersonic excitation, consisting of multiple lateral and transverse wakes Shear Wave: had a single-cone structure In far field, the wake structure in experiment is comparable to Dubin’s theory of wakes in dusty plasma crystal

32 Solar system Rings of Saturn Comet tails Basic physics Coulomb crystals Waves Manufacturing Particle contamination (Si wafer processing) Nanomaterial synthesis Who cares about dusty plasmas?

33 0 80 160 9 months data in 1999 Dusty plasma publications in APS & AIP journals

34 Coulomb force –Interparticle interaction is repulsive Coulomb (Yukawa) –External confinement by natural electric fields present in plasma

Download ppt "Mach Cones in a 2D Dusty Plasma Crystal J. Goree Dept. of Physics and Astronomy, University of Iowa with results from V. Nosenko, Z. Ma, and D. Dubin Supported."

Similar presentations

Empirical Rule for Phase Transitions in Dusty Plasma Crystals A.A. Samarian School of Physics, University of Sydney, Sydney, NSW 2006, Australia.

Empirical Rule for Phase Transitions in Dusty Plasma Crystals A.A. Samarian School of Physics, University of Sydney, Sydney, NSW 2006, Australia.
Particle’s Dynamics in Dusty Plasma with Gradients of Dust Charges

Particle’s Dynamics in Dusty Plasma with Gradients of Dust Charges
Erdem Oz* USC E-164X,E167 Collaboration Plasma Dark Current in Self-Ionized Plasma Wake Field Accelerators

Erdem Oz* USC E-164X,E167 Collaboration Plasma Dark Current in Self-Ionized Plasma Wake Field Accelerators
Alex.A. Samarian and Brian.W. James School of Physics, University of Sydney, NSW 2006, Australia Sheath edge location The charge of dust particles in sheath.

Alex.A. Samarian and Brian.W. James School of Physics, University of Sydney, NSW 2006, Australia Sheath edge location The charge of dust particles in sheath.
Rotating Wall/ Centrifugal Separation John Bollinger, NIST-Boulder Outline ● Penning-Malmberg trap – radial confinement due to angular momentum ● Methods.

Rotating Wall/ Centrifugal Separation John Bollinger, NIST-Boulder Outline ● Penning-Malmberg trap – radial confinement due to angular momentum ● Methods.
Types of Waves Harmonic Waves Sound and Light Waves

Types of Waves Harmonic Waves Sound and Light Waves
Flinders University of South Australia Leon Mitchell Nathan Prior University of Sydney Brian James Alex Samarian Felix Cheung.

Flinders University of South Australia Leon Mitchell Nathan Prior University of Sydney Brian James Alex Samarian Felix Cheung.
Plasmas in Space: From the Surface of the Sun to the Orbit of the Earth Steven R. Spangler, University of Iowa Division of Plasma Physics, American Physical.

Plasmas in Space: From the Surface of the Sun to the Orbit of the Earth Steven R. Spangler, University of Iowa Division of Plasma Physics, American Physical.
electrostatic ion beam trap

electrostatic ion beam trap
Shock wave propagation across the column of dusted glow discharge in different gases. A.S.Baryshnikov, I.V.Basargin, M.V.Chistyakova Ioffe Physico-Technical.

Shock wave propagation across the column of dusted glow discharge in different gases. A.S.Baryshnikov, I.V.Basargin, M.V.Chistyakova Ioffe Physico-Technical.
TEST GRAINS AS A NOVEL DIAGNOSTIC TOOL B.W. James, A.A. Samarian and W. Tsang School of Physics, University of Sydney NSW 2006, Australia

TEST GRAINS AS A NOVEL DIAGNOSTIC TOOL B.W. James, A.A. Samarian and W. Tsang School of Physics, University of Sydney NSW 2006, Australia
Phonons in a 2D Yukawa triangular lattice: linear and nonlinear experiments Dept. of Physics and Astronomy, University of Iowa supported by DOE, NASA,

Phonons in a 2D Yukawa triangular lattice: linear and nonlinear experiments Dept. of Physics and Astronomy, University of Iowa supported by DOE, NASA,
Chapter 4 Waves in Plasmas 4.1 Representation of Waves 4.2 Group velocity 4.3 Plasma Oscillations 4.4 Electron Plasma Waves 4.5 Sound Waves 4.6 Ion Waves.

Chapter 4 Waves in Plasmas 4.1 Representation of Waves 4.2 Group velocity 4.3 Plasma Oscillations 4.4 Electron Plasma Waves 4.5 Sound Waves 4.6 Ion Waves.
F. Cheung, A. Samarian, B. James School of Physics, University of Sydney, NSW 2006, Australia.

F. Cheung, A. Samarian, B. James School of Physics, University of Sydney, NSW 2006, Australia.
Partially ionized gas -contains IONS, ELECTRONS and neutral particles.

Partially ionized gas -contains IONS, ELECTRONS and neutral particles.
Physics of fusion power Lecture 11: Diagnostics / heating.

Physics of fusion power Lecture 11: Diagnostics / heating.
The Spatiotemporal Evolution of an RF Dusty Plasma: Comparison of Numerical Simulations and Experimental Measurements Steven Girshick, Adam Boies and Pulkit.

The Spatiotemporal Evolution of an RF Dusty Plasma: Comparison of Numerical Simulations and Experimental Measurements Steven Girshick, Adam Boies and Pulkit.
Reinisch_85.5111 85. 511 Solar Terrestrial Relations (Cravens, Physics of Solar Systems Plasmas, Cambridge U.P.) Lecture 1- Space Environment –Matter in.

Reinisch_ Solar Terrestrial Relations (Cravens, Physics of Solar Systems Plasmas, Cambridge U.P.) Lecture 1- Space Environment –Matter in.
Prof. Reinisch, EEAS 85.483/511. 4.1 Simple Collision Parameters (1) There are many different types of collisions taking place in a gas. They can be grouped.

Prof. Reinisch, EEAS / Simple Collision Parameters (1) There are many different types of collisions taking place in a gas. They can be grouped.
Measurement of the Charge of a Particle in a Dusty Plasma Jerome Fung, Swarthmore College July 30, 2004.

Measurement of the Charge of a Particle in a Dusty Plasma Jerome Fung, Swarthmore College July 30, 2004.

Similar presentations

Ads by Google