1 Eniko Madarassy Reconnections and Turbulence in atomic BEC with C. F. Barenghi Durham University, 2006.

Slides:



Advertisements
Similar presentations
P.W. Terry K.W. Smith University of Wisconsin-Madison Outline
Advertisements

Pressure and Kinetic Energy
Vortex instability and the onset of superfluid turbulence
Two scale modeling of superfluid turbulence Tomasz Lipniacki
Rotations and quantized vortices in Bose superfluids
University of Newcastle, UK Collisions of superfluid vortex rings Carlo F. Barenghi Nick Proukakis David Samuels Christos Vassilicos Charles Adams Demos.
Quantum Turbulence: -From Superfluid Helium to Atomic Bose-Einstein Condensates- Makoto TSUBOTA Department of Physics, Osaka City University, Japan Thanks.
The left panel shows a suspension of hydrogen particles just above the transition temperature. The right panel shows the same particles after the fluid.
An introduction to superfluidity and quantum turbulence
Dynamics and Statistics of Quantum Turbulence at Low Temperatures
Self-propelled motion of a fluid droplet under chemical reaction Shunsuke Yabunaka 1, Takao Ohta 1, Natsuhiko Yoshinaga 2 1)Department of physics, Kyoto.
Numerical Method for Computing Ground States of Spin-1 Bose-Einstein Condensates Fong Yin Lim Department of Mathematics and Center for Computational Science.
VORTEX RECONNECTIONS AND STRETCHING IN QUANTUM FLUIDS Carlo F. Barenghi School of Mathematics, Newcastle University, Newcastle upon Tyne, UK.
Plasma Astrophysics Chapter 7-1: Instabilities I Yosuke Mizuno Institute of Astronomy National Tsing-Hua University.
Direct numerical simulation study of a turbulent stably stratified air flow above the wavy water surface. O. A. Druzhinin, Y. I. Troitskaya Institute of.
1 Enikö Madarassy Vortex motion in trapped Bose-Einstein condensate Durham University, March, 2007.
INTRODUCTION OF WAVE-PARTICLE RESONANCE IN TOKAMAKS J.Q. Dong Southwestern Institute of Physics Chengdu, China International School on Plasma Turbulence.
Cosmological Structure Formation A Short Course
Transverse force on a magnetic vortex Lara Thompson PhD student of P.C.E. Stamp University of British Columbia July 31, 2006.
World of zero temperature --- introduction to systems of ultracold atoms National Tsing-Hua University Daw-Wei Wang.
Anderson localization in BECs
Guillermina Ramirez San Juan
Non-collisional ion heating and Magnetic Turbulence in MST Abdulgader Almagri On behalf of MST Team RFP Workshop Padova, Italy April 2010.
Bose-Einstein Condensate Fundaments, Excitation and Turbulence Vanderlei Salvador Bagnato Instituto de Física de São Carlos – Universidade de São Paulo.
Bose-Einstein Condensate Fundaments, Excitation and Turbulence Vanderlei Salvador Bagnato Instituto de Física de São Carlos – Universidade de São Paulo.
The Air-Sea Momentum Exchange R.W. Stewart; 1973 Dahai Jeong - AMP.
System and definitions In harmonic trap (ideal): er.
Wave-Particle Interaction in Collisionless Plasmas: Resonance and Trapping Zhihong Lin Department of Physics & Astronomy University of California, Irvine.
Cosmological Reconstruction via Wave Mechanics Peter Coles School of Physics & Astronomy University of Nottingham.
Academic Training Lectures Rocky Kolb Fermilab, University of Chicago, & CERN Cosmology and the origin of structure Rocky I : The universe observed Rocky.
ACKNOWLEDGMENTS This research was supported by the National Science Foundation of China (NSFC) under grants , , , the Specialized.
Wind Energy Program School of Aerospace Engineering Georgia Institute of Technology Computational Studies of Horizontal Axis Wind Turbines PRINCIPAL INVESTIGATOR:
Bose-Einstein Condensation and Superfluidity Lecture 1. T=0 Motivation. Bose Einstein condensation (BEC) Implications of BEC for properties of ground state.
Carlo F. Barenghi School of Mathematics University of Newcastle, UK Exotic turbulence opportunities in superfluid helium.
V.B.Efimov1,2 and P.V.E.McClintock2
Blackbody Radiation Wien’s displacement law : Stefan-Boltzmann law :
Dynamics of Polarized Quantum Turbulence in Rotating Superfluid 4 He Paul Walmsley and Andrei Golov.
Anatoli Polkovnikov Krishnendu Sengupta Subir Sachdev Steve Girvin Dynamics of Mott insulators in strong potential gradients Transparencies online at
Anomalous resistivity due to lower-hybrid drift waves. Results of Vlasov-code simulations and Cluster observations. Ilya Silin Department of Physics University.
1 Physics of GRB Prompt emission Asaf Pe’er University of Amsterdam September 2005.
Makoto Tsubota,Tsunehiko Araki and Akira Mitani (Osaka), Sarah Hulton (Stirling), David Samuels (Virginia Tech) INSTABILITY OF VORTEX ARRAY AND POLARIZATION.
Numerical simulations of thermal counterflow in the presence of solid boundaries Andrew Baggaley Jason Laurie Weizmann Institute Sylvain Laizet Imperial.
Lecture IV Bose-Einstein condensate Superfluidity New trends.
Electron inertial effects & particle acceleration at magnetic X-points Presented by K G McClements 1 Other contributors: A Thyagaraja 1, B Hamilton 2,
VORTICES IN BOSE-EINSTEIN CONDENSATES TUTORIAL R. Srinivasan IVW 10, TIFR, MUMBAI 8 January 2005 Raman Research Institute, Bangalore.
Lecture 2. Why BEC is linked with single particle quantum behaviour over macroscopic length scales Interference between separately prepared condensates.
The Stability of Laminar Flows - 2
Numerical study of flow instability between two cylinders in 2D case V. V. Denisenko Institute for Aided Design RAS.
RFX-mod Program Workshop, Padova, January Current filaments in turbulent magnetized plasmas E. Martines.
Acoustic wave propagation in the solar subphotosphere S. Shelyag, R. Erdélyi, M.J. Thompson Solar Physics and upper Atmosphere Research Group, Department.
Condensed matter physics in dilute atomic gases S. K. Yip Academia Sinica.
Optically Trapped Low-Dimensional Bose Gases in Random Environment
Chapter 2. Physical processes responsible for evolution and downstream breakdown of a subsonic round jet Multimedia files Nos. 2.1 – 2.8 The results of.
The Tale of Two Tangles: Dynamics of "Kolmogorov" and "Vinen" turbulences in 4 He near T=0 Paul Walmsley, Steve May, Alexander Levchenko, Andrei Golov.
Association Euratom-CEA TORE SUPRA EAST, China 07/01/2010Xiaolan Zou1 Xiaolan ZOU CEA, IRFM, F Saint-Paul-Lez-Durance, France Heat and Particle Transport.
Y. Kishimoto 1,2), K. Miki 1), N. Miyato 2), J.Q.Li 1), J. Anderson 1) 21 st IAEA Fusion Energy Conference IAEA-CN-149-PD2 (Post deadline paper) October.
Tree methods, and the detection of vortical structures in the vortex filament method Andrew Baggaley, Carlo Barenghi, Jason Laurie, Lucy Sherwin, Yuri.
K.M.Shahabasyan, M. K. Shahabasyan,D.M.Sedrakyan
Congresso del Dipartimento di Fisica Highlights in Physics –14 October 2005, Dipartimento di Fisica, Università di Milano Solitons in attractive.
Subir Sachdev Superfluids and their vortices Talk online:
May 23, 2006SINS meeting Structure Formation and Particle Mixing in a Shear Flow Boundary Layer Matthew Palotti University of Wisconsin.
Soliton-core filling in superfluid Fermi gases with spin imbalance Collaboration with: G. Lombardi, S.N. Klimin & J. Tempere Wout Van Alphen May 18, 2016.
Superfluidity and Quantum Vortices. Outline of the presentation Bose-Einstein Condensation Superfluidity Quantum Vortix.
Simulation of a self-propelled wake with small excess momentum in a stratified fluid Matthew de Stadler and Sutanu Sarkar University of California San.
INTRODUCTION and MOTIVATIONS
Exotic turbulence opportunities in superfluid helium
Lecture 30 Wave Equation and solution (Chap.47)
Ehud Altman Anatoli Polkovnikov Bertrand Halperin Mikhail Lukin
Lecture 29 Oscillation, linear superposition, and wave
a = 0 Density profile Relative phase Momentum distribution
Presentation transcript:

1 Eniko Madarassy Reconnections and Turbulence in atomic BEC with C. F. Barenghi Durham University, 2006

2 Outline Gross - Pitaevskii / Nonlinear Schrödinger Equation Vortices (phase, density, quantized circulation) Phase imprinting produces a soliton-like disturbance which decays into vortices Sound energy and Kinetic energy Conclusions

3 The Gross-Pitaevskii equation in a rotating system also called Nonlinear Schrödinger Equation The GPE governs the time evolution of the (macroscopic) complex wave function Ψ(r,t) Boundary condition at infinity: Ψ(x,y) = 0 The wave function is normalized: = wave function = reduced Planck constant = dissipation [1] = chemical potential m = mass of an atom = rotation frequency of the trap = centrifugal term g = coupling constant [1] Tsubota et al, Phys.Rev. A (2002)

4 Vortices Vortex : a flow involving rotation about an axis = Madelung transformation = Density = 0, on the axis = Phase: changes from 0 to 2π going around the axis Quantized circulation:

5 Aim / motivations Creation of mini-turbulent vortex system Large scale turbulence of quantized vortices is studied in superfluid 3He-B and 4He. Disadvantage of turbulence in BEC: small system and few vortices Advantage: relatively good visualization of individual vortices, more detail Particularly: can study detail of transformation of kinetic energy into acustic energy [2], (which occurs in liquid helium too). Because of: 1) vortex reconnection [3] 2) vortex acceleration [4] [2] C. Nore, M. Abid, and M.E. Brachet., Phys. Rev. Lett. 78, 3896 (1997 ) [3] M.Leadbeater, T. Winiecki, D.S. Samuels, C.F. Barenghi, C.S. Adam, Phys. Rev. Lett. 86, 1410 (2001) [4] N.G. Parker, N.P. Proukakis, C.F. Barenghi and C.S. Adams, Phys. Rev. Lett. 92, (2004)

6 Decay of soliton-like perturbation into vortices Dark solitons are observed in BECs [5],[6], they are produced with the ” Phase Imprinting ” method [7]. For example: We imprint the phase in two ways: Case I: Case II: in upper two quadrants in upper left quadrant (x 0) and bottom right quadrant (x > 0 and y < 0) In both cases soliton-like perturbations are produced. Solitary waves in matter waves are characterized by a particular local density minimum and a sharp phase gradient of the wave function at the position of the minimum. [5] S. Burger et al., Phys.Rev. Lett. 83,5198 (1999); J. Denschlag et al., Science 287, 97, (2000) [6] N.P. Proukakis, N.G. Parker, C.F. Barenghi, C.S. Adams, Phys. Rev. Lett. 93, , (2004) [7] L. Dobrek et al., Phys. Rev. A 60, R3381 (1999)

7 Case I. Snapshots of the density profile The perturbation was created from the phase change The original sound wave The perturbation bends and decays into the vortex pair Sound waves due to the decay of the perturbation

8 Case I. (continued) The perturbation starts to move and bends because of the difference in the density Higher velocity Sound waves due to the vortex pair production Five pairs of vortices Three pairs go into boundary. Two pairs survive.

9 (Case I. Continued) Another view Sound waves due to the decay of the perturbation. The perturbation bends and starts to move. The perturbation decays into the vortex pair. The soliton like perturbation.

10 ( Case I continued) Phase: Random phase region:  0 Large fluctuation of the phase: Im  0 Re  0 imprinting

11 Transfer of the energy from the vortices to the sound field Divide the total energy into a component due to the sound field E s and a component due to the vortices E v [8] Procedure to find E v at a particular time: 1. Compute the total energy. 2. Take the real-time vortex distribution and impose this on a separate state with the same a) potential and b) number of particles 3. By propagating the GPE in imaginary time, the lowest energy state is obtained with this vortex distribution but without sound. 4. The energy of this state is E v. Finally, the the sound energy is: E s = E – E v [8] N.G. Parker and C.S. Adams, Phys. Rev. Lett. 95, (2005)

12 Case II, Phase imprinting applied to vortex lattice in rotating frame Snapshots of the density and phase profile at the times:

13 The sound energy in connection with the total energy Due to the new level of energy by the discontinuity, the total energy changes. Dimensionless unit: ( The time units is less than 1ms) Time:

14 Conclusions: By generating a discontinuity in the phase, the system tries to smooth out this change and generate a soliton-like perturbation, which decays into vortices. We observe transformation of kinetic energy into sound energy. The sound energy is the biggest contribution to the change of the total energy. Two contributions to the sound energy. First, from the phase change and second from the interaction between vortex-antivortex.