i. grigorieva, l. vinnikov, a. geim (manchester) v. oboznov, s. dubonos (chernogolovka)
TRANSCRIPT
I. Grigorieva, L. Vinnikov, A. Geim(Manchester)
V. Oboznov, S. Dubonos (Chernogolovka)
• Vortices in small superconductors (size R ~ ξ,λ) expected to behave similar to electrons in artificial atoms, i.e. obey specific rules for shell filling, exhibit magic numbers, etc.
• In confined geometries, superconducting wave function must obey boundary conditions which determine total vorticity L
• Vortex states are further influenced by vortex interactions with screening currents (for R > λ)
• Numerical studies of vortex states exist but so far no direct observations
• We present direct observations of vortex states in small superconducting dots by magnetic decoration
Motivation
Starting Nb films: λ(0) 90 nm; ξ(0) 15 nm; Hc2(0) 1.5 T;
6; Tc=9.1 K; thickness d = 150 nm > ξ, λ
Vortex structure in a macroscopic Nb film. External field Hext = 80 Oe
200 µm
20 µm
5 µm
Each structure contained circular disks, squares and triangles of four different sizes: 1µm; 2 µm; 3µm; 5 µm
Over 500 dots decorated in each experiment (same field, temperature, decoration conditions)
field-cooling in perpendicular magnetic field
external magnetic field varying between 20 and 160 Oe, i.e., H/Hc2 = 0.002 – 0.016, where Hc2(3.5 K) 1 T;
experimental details
H decoration captures snapshotsof vortex states at T 3.5 K =0.4Tc;
thickness of all nanostructured samples d = 150 nm > ξ, λ
L = 9
L = 25 (3,8,14)
L = 94
despite strong pinning, confinement has dominating effect on vortex states:
well defined shell structures observed for L 35 in circular disks;
a variety of states with triangular / square symmetries observed for L 15 for triangular and square dots
for larger L (L>30-35), vortex arrangements are less well defined and for L > 50 become disordered, similar to macroscopic films
due to many different combinations of Hext
values and dot sizes, almost all possible vorticities between L=0 and L 50 were observed (L = 0,1,2,3,4,5,6,…)
for all values of vorticity L, external filed (total flux) required for nucleation of L vorticies significantly exceeds corresponding field for a macroscopic film
0
10
20
30
40
0 5 10 15 20 25
(0)(1)(2)(3)(4)(5)(1,5)(1,6)(1,7)(1,8)(2,7)(2,8)(3,7)(3,8)(4,10)(1,5,11) (1,6,12)(1,6,13)(1,6,14)
L = /0
L
/ 0
Vorticity vs field
B.J. Baelus and F.M. Peeters, Phys. Rev. B 65, 104515, 2002
experiment, disk size R 100ξ
nucleation of the first vortex requires magnetic flux corresponding to over 30
states with small vorticities are stable overappreciable field intervals, e.g. for a 2µm disk, H 20 Oe for transition to L=1; H 10 Oefor transition to L=2
numerical study, R = 6ξ
0
1
2
3
4
0 5 10 15 20 25
L
(-
0L)/
L 0
Vorticity vs field
0
10
20
30
40
frequency
(2,7) (2,8) (3,3,3)(1,8) (3,7)
0
20
40
60
fre
qu
en
cy
(2,8)(2,7) (3,7)(3,3,3) (1,8)
at least two or three different states observed in every experiment in dots of nominally the same size
2 m dots, Hext= 80 Oe
3 m dots, Hext= 60 Oe
Multiplicity of vortex arrangements
variations in dot sizes, shape irregularities lead to variations in flux up to 0
small differences in energy of different states with same L implied
21
22
23
7 8 9 10 11 12 13
(1,8)(2,8)(3,7)(3,8)
L
/ 0 0.50
Multiplicity of vortex arrangements
0
5
10
15
20
0 4 8 12
L
/ 0
(0)(1)
(2)(3)
(5)(1,5)
(6)
(4)
(1,6)
(1,7) (1,8)
(2,7)
(2,8)
(3,7) (3,8)
Evolution of vortex states
Comparison with theory
B.J. Baelus, L.R.E. Cabral,F.M. Peeters, Phys.Rev.B69, 064506 (2004)
observed vortex states in good agreement with numerical simulations
Magic numbers
we are able to
identify magic numbers (maximum numbers of vortices in each shell before the next shell nucleates) identify shell filling rules
…
L = 5
L = 6
L = 7 L = 8
…after that new vortices appear in either the first or second shell:
L=11 (3,8)L=10 (3,7)
L=10 (2,8)
L=9 (2,7)
Magic numbers
… and this continues until the total vorticity reaches L=14 (L1=4; L2=10)
Magic numbers… third shell appears at L>14 in the form of one vortex in the centre …
L=17 (1,5,11) L=18 (1,6,11)… after that additional vortices nucleate in either first, second or third shell until L3 reaches 16…
L=22 (2,7,13) L=24 (3,7,14)
Magic numbers
… fourth shell appears at L3>18 in the form of one vortex in the centre, and so on …
L=35 (1,5,11,18)
rules of shell filling similar to electrons in artificial atoms (V.M. Bedanov and F.M. Peeters, Phys. Rev.B 49,667, 1994)
magic numbers: one shell L1=6 two shells L2=10 three shells L3=18 …..
Vortex states in triangular dots
Vortex states in square dots
Conclusions
direct observations of multiple vortex states in confined geometry
low-vorticity states (L<4) are stable over surprisingly large intervals of magnetic field
well defined shell structures in circular geometry
magic numbers for vortex shell filling
L=20 (1,6,13)Hext=160 Oe
L=18 (1,6,11)Hext = 30 Oe
L=21 (1,7,13)Hext=160 Oe
vortex configurations do not change with increasing external field