cascade of vortex loops intiated by single reconnection of quantum vortices
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Cascade of vortex loops intiated by single reconnection of quantum vortices
Miron Kursa1
Konrad Bajer1
Tomasz Lipniacki2
1University of Warsaw
2Polish Academy of Sciences, Institute of Fundamental Technological Research
1. Self-similar solutions for LIA
2. Vortex rings cascades (BS, GP)
3. Energy dissipation in T→0 limit
3
Motion of a vortex filament
Biot-Savartlaw
: non-dimensional friction parameter, vanishes at T=0
4
Local Induction Approximation
For T>0: >0 vortex ring shrinks
Self-similar and quasi-static solutions Lipniacki PoF 2003, JFM 2003
Quantum vortex shrinks:
0
2dc
)(),( nbssss ct
0
2222
0
232
22
2
2
dccc
ccc
c
cc
t
dccccccct
c
nbbtnnt , , ccFrenet Seret equations
Shape-preserving (self-similar) solutions
t
ttt Ss )(),(
. ,1
,1
, ,2
tl
tTtt
Kt
c
tt
22
2
2
22
0
2222
0
232
TlTldKTTK
K
TKTKK
K
KTK
KlKldKKKKTKTKTK
l
l
The simplest shape-preserving solution (2003) In the case when transformation is a pure homothety we get analytic solution in implicit form:
K
K
KKpKKK
KdKl
K
K
T ,
)()/ln()(
0
2200
22
Self-crossings for Г<8º
and sufficietly small α/β
Shape preserving solution: general case
Logarithmic spirals on cones
4-parametric class
Wing tip vortices
10
c(»;t)=c0pt
¿(»;t)=»2t
Buttke, 1988
THIS SOLUTION HAS CONSTANT CURVATURE !
K
K
KKpKKK
KdKl
K
K
T ,
)()/ln()(
0
2200
22
Limit of shape preserving solution for α→0 ?
11
RootM ean SquareDistance(RM SD)asa function of®
W hen ® ¡! 0
When α→0
Shape preserving solutions
„tend locally” to
Buttke solution
α=1, 0.1, 0.01, 0.001, Buttke
YES
12
Does LIA time-dependent dynamics tend to those similarity solutions ?
Yes
® = 0; ¡ = 57±
® = 0; ¡ = 57± :
13
Does LIA time-dependent dynamics tend to those similarity solutions ?
Yes
® = 0:001; ¡ = 1:4± :
14
Buttke,JCP,1988
·0 = 1:3
¡ ¼ 5±
® = 0; ®0= 0
LIA solutions for Г<8º have self-crossings
DO THEY HAPPEN ALSO INBIOT-SAVART DYNAMICS ?
16
Biot-Savart simulations
17
Biot-Savart simulations
18
Biot-Savart
LIA
Crossings happen below the respective lines
19
Gross - Pitaevski equation
ª 0 = f(r)ei© : f(r)¡¡¡!r! 1
1 :.
vortex
ª
· =Hdl¢v = 2¼~=m :
.
20
Gross - Pitaevski simulations
¡ = 4± :
Г=4º Dufort-Frankel scheme (Lai et al. 2004)
21
Kursa, M.; Bajer, K. & Lipniacki, T. Cascade of vortex loops initiated by a single reconnection of quantum vortices Phys. Rev. B, 2011, 83, 014515
Kerr, PRL 2011
Rings generation from reconnections of antiparallel vortices
Quasi-static solution, 2003 In the case when transformation is a pure translation we get analyticsolution:
22
0
22
0
0
,
)tanh( ),sech(
cB
cA
ABAcc
AAtcdRdRt /))ln(cosh(,)(qsin,)cos(q),( 220
s
where 220q ),sech( AcAR
Self-crossings for α/β <0.45, Number of S-C tends to infinity as α/β tends to zero
)0,()()(),( sWs ttt
Vortex loops cascades as a potential mechanism of
energy dissipation?
Evaporation of a packet of quantized vorticity, Barenghi, Samuels, 2002
26
Diameters of subsequent rings form
geometrical sequence
Times of subsequent ring detachments form
geometrical sequence
„Lost” line length
27
°B S
Average radius of curvature in the tangle
(Barenghi & Samuels 2004)
Frequency of reconnections
Total line length lost in single reconnection
„transparent tangle”
28
Mean free path of a ring of diameter in the tangle of line density
„OPAQUE TANGLE”
d
L
Total line length lost in single reconnection
„opaque tangle”
29
LINE LENGTH DECAY AT ZERO TEMPERATURE
Transparent tangle
Opaque tangle
μ – Fraction of reconnections leading to cascades of rings®
Waele, Aartz, 1994, μ=0
Uniform distribution of reconnection angles
μ310
2
cos1
BS
Thermally driven Mechanically driven
Baggaley,Shervin,Barenghi,Sergeev 2012
31
a
Feynman's cascade, 1955
reconnections kelvons dissipation
Line dissipation decreases like
Loop cascade generation Line length dissipation decreases like
t¡ 2
Svistunov, 1995 …
Efficient provided that μ is large enough
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