superconductivity in nanowires and quantum devices · superconductivity in nanowires and quantum...
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![Page 1: Superconductivity in nanowires and quantum devices · Superconductivity in nanowires and quantum devices Alexey Bezryadin Department of Physics University of Illinois at Urbana-Champaign](https://reader030.vdocument.in/reader030/viewer/2022040613/5f077a8b7e708231d41d2eee/html5/thumbnails/1.jpg)
Superconductivity in nanowires and
quantum devices
Alexey Bezryadin
Department of Physics
University of Illinois at Urbana-Champaign
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Electrical resistance of some metals drops to zero below a certain temperature
which is called "critical temperature“ (H. K. O. 1911)
Superconductivity discovery
How to observe superconductivity
- Take Nb wire
- Connect to a voltmeter and a current
source
- Put into helium Dewar
- Measure electrical resistance
T (K)
R (Ohm)
10 300
A
V
Dewar
with liquid Helium (4.2K)
Nb wire
Rs
Heike Kamerling Onnes
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Meissner effect – the key signature of
superconductivity
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Magnetic levitation
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Magnetic levitation train
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tin
Discovery of the
supercurrent, known now
as the proximity effect, in
superconductor-normal-
superconductor (SNS)
junctions
Superconductor (tin)
Non-superconductor (normal metal, i.e., Ag)
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tin
Explanation of the supercurrent in SNS
junctions --- Andreev reflection
A.F. Andreev, 1964
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Little-Parks effect (’62)The basic principle: magnetic field induces non-zero vector-potential, which produces non-zero
superfluid velocity, thus reducing the Tc. Thus vector-potential is proven to have a physical
effect in the currents and the order parameter of the superconductor
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Superconducting vortices produced by
external magnetic field
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Magnetic field creates vortices--
Vortices cause dissipation (i.e. a non-zero electrical resistance)!
I-current
B -magnetic field
Vortex core: normal, not superconducting; diameter x~10 nm
Ψ= |Ψ| exp(-iφ)
The order parameter:
amplitudephase
Vortices introduce electrical resistance to
otherwise superconducting materials
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DC transport measurement scheme for nanowires
Phase slip events are shown as red dots
filter
filter
filter
filter
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Electrical resistance is zero only if current is not too strong
I (current)
V (voltage)
Superconducting regime:
Big question: is the resistance exactly zero?
Normal state—Ohm’s law
Ic
Superconductivity: very basic introduction
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How to use voltage to determine the rate of phase slips?
Prove this: 2eV=ħ dφ/dt ????
Remember the Shrȍdinger Equation: i ħ(dΨ/dt)=E Ψ
According to Shrȍdinger Equation, φ=Et/ ħ and so
dφ /dt= E/ ħ , where E is the energy.
According to Bardeen-Cooper-Schrieffer (BCS) theory, electrons
form a condensate of pairs, so the energy is E=2eV,
where V is the electric potential and e is the electronic charge.
Thus:
2eV= ħ dφ/dt
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Transport properties: Little’s Phase Slip (PS)
W. A. Little, “Decay of persistent currents in small superconductors”,
Physical Review, V.156, pp.396-403 (1967).
∆(x)=│∆(x)│exp[iφ]
Two types of phase slips (PS) can be expected:
1. The usual, thermally activated phase slips (TAPS)
2. Quantum phase slip (QPS)
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Fabrication of nanowires
Method of Molecular Templating
Bezryadin, Lau, Tinkham, Nature 404, 971 (2000)
Si/ SiO2/SiN substrate with undercut
~ 0.5 mm Si wafer
500 nm SiO2
60 nm SiN
Width of the trenches ~ 50 - 500 nm
HF wet etch for ~10 seconds
to form undercut
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Schematic picture of the pattern
Nanowire + Film Electrodes used in
transport measurements
4 nm
TEM image of a wire shows amorphous morphology.
Nominal MoGe thickness = 3 nm
Sample Fabrication
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Low -T Filter
Room Temp
Low Temp
Sample
pi-Filter
Cernox
Thermometer
Measurement Scheme: Importance of RF noise filtering
Sample mounted on the 3He
insert.Circuit Diagram
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Procedure (~75% Success)
- Put on gloves
- Put grounded socket for mounting in vise with grounded
indium dot tool connected
- Spray high-backed black chair all over and about 1 m
square meter of ground with anti-static spray
- DO NOT use green chair
- Not sure about short-backed black chairs
- Sit down
- Spray bottom of feet with anti-static spray
- Plant feet on the ground. Do not move your feet again for
any reason until mounting is finished.
- Mount sample
- Keep sample in grounded socket until last possible
moment
- Test samples in dipstick at ~1 nA
Tony Bollinger's sample-mounting procedure in winter in Urbana
(~2004)
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Possible Origin of Quantum Phase Slips – electromagnetic noise
101
102
103
104
543210
R (
T)
T (K)
He3 He4
origin of quantum phase slips
101
102
103
104
54321
R (
T)
T (K)
QPS off
QPS on
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Search for QPS at high bias currents: Measuring the
fluctuations of the switching current
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Saturation of the switching current standard deviation gives
evidence to MQT
1) Kurkijarvi power law is observed at high
temperatures. This proves that we are in
the single-phase slip regime.
2) Such saturation is a strong indicator of
macroscopic quantum tunneling.
3) The mean value of the switching
currenet does not saturates, as expected.
This rules out external noise and
presence of out-of-equilibrium hot
electrons.
T. Aref et al., Phys. Rev. B 86, 024507 (2012)
M. Sahu, M.-H. Bae, A. Rogachev, D. Pekker, T. Wei,
N. Shah1, P. M. Goldbart, and A. Bezryadin,
Nature Physics 5, 503 (2009).
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Dichotomy in nanowires:
Evidence for superconductor-
insulator transition (SIT)
Bollinger, Dinsmore, Rogachev, Bezryadin,
Phys. Rev. Lett. 101, 227003 (2008)
−= 400100sheetR
The difference between samples is the
amount of the deposited Mo79Ge21.
R=V/I I~3 nA
Can the insulating behavior
be due to Anderson
localization of the BCS
condensate?
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Useful Expression for the Free Energy of a Phase Slip
“Arrhenius-Little” formula for the wire resistance:
RAL ≈ RN exp[-ΔF(T)/kBT]
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Linearity of the Schrödinger’s equation
Suppose Ψ1 is a valid solution of the Schrödinger equation:
𝑖ℏ𝜕𝜓1
𝜕𝑡=𝜕2𝜓1
𝜕𝑥2+ 𝑈(𝑥)𝜓1
And suppose that Ψ2 is another valid solution of the Schrödinger equation:
𝑖ℏ𝜕𝜓2
𝜕𝑡=𝜕2𝜓2
𝜕𝑥2+ 𝑈(𝑥)𝜓2
Then (Ψ1 + Ψ2)/√2 is also a valid solution, because:
𝒊ℏ𝝏(𝝍𝟏 +𝝍𝟐)
𝝏𝒕=𝝏𝟐(𝝍𝟏 +𝝍𝟐)
𝝏𝒙𝟐+𝑼(𝒙)(𝝍𝟏 +𝝍𝟐)
The state (Ψ1 + Ψ2)/√2 is a new combined state which is called “quantum superposition” of state (1) and (2)
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Quantum tunneling
U
x
George Gamow
(He also developed
Big Bang theory)
𝝍|𝒕=𝟎
𝝍(𝒕)
1 2
Quantum tunneling is possible
since quantum superpositions of
states are possible.
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Schrödinger cat –
the ultimate macroscopic quantum phenomenon
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Schrödinger cat – thought experiment
Hans Geiger
Geiger counter
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What sort of tunneling we will consider?
-Red color represents some strong current in the superconducting wire loop
-Blue color represents no current or a much smaller current in the loop
tunnel
Is>0 Is=0
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Previous results relate loops with insulating
interruptions (SQUIDs)
-Red color represents some strong current in the superconducting loop
-Blue color represents no current or very little current
in the superconducting loop
tunnel
Is
Insulting gap
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Leggett’s prediction
for macroscopic quantum tunneling (MQT) in SQUIDs
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MQT report by Kurkijarvi and collaborators (1981)
Sigma~T2/3
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What determines the period of oscillation?(A simple guess for the period would be ΔB~ Φ0/2ab.
This prediction deviates from the result by a factor 100!)
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Phase gradiometers templated by DNA
D. Hopkins, D. Pekker,
P. Goldbart, and A. Bezryadin,
Science 308, 1762–1765 (2005).
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mTab
Period 10~2
0=
The width of the leads was
changed from 14480 nm to
8930 nm
The period changed from
77.5 μT to 128 μT
Little-Parks effect.
The period of the oscillation is inversely proportional to the width
of the electrodes
Correct field period:
here 2l - the width of the leads
G = .916 is the
Catalan number
usual SQUID estimate:
here 2a-distance between the
wires;
b- length of wires
alGB
48
0
2=
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SQUID – superconducting quantum interference deviceSQUID helmet project at Los Alamos
SQUIDs, or Superconducting Quantum Interference Devices, invented in 1964 by Robert Jaklevic, John Lambe, Arnold Silver, and James
Mercereau of Ford Scientific Laboratories, are used to measure extremely small magnetic fields. They are currently the most sensitive
magnetometers known, with the noise level as low as 3 fT•Hz−½. While, for example, the Earth magnet field is only about 0.0001 Tesla, some
electrical processes in animals produce very small magnetic fields, typically between 0.000001 Tesla and 0.000000001 Tesla. SQUIDs are
especially well suited for studying magnetic fields this small.
Measuring the brain’s magnetic fields is even much more difficult because just above the skull the strength of the magnetic field is only about 0.3
picoTesla (0.0000000000003 Tesla). This is less than a hundred-millionth of Earth’s magnetic field. In fact, brain fields can be measured only with
the most sensitive magnetic-field sensor, i.e. with the superconducting quantum interference device, or SQUID.
Magnetic field scales:
Earth field: ~1G
Fields inside animals:
~0.01G-0.00001G
Fields on the human brain:
~0.3nG
This is less than a hundred-
millionth of the Earth’s
magnetic field.
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Measuring nanowires within GHz resonators.
Detection of individual phase slips.
A. Belkin et al, Appl. Phys. Lett. 98, 242504 (2011)
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Resonators used to detect single phase slips (SPS) and double phase slips (DPS)
T = 360 mK
f = f0(H=0)
A. Belkin et al, PRX 5, 021023 (2015)
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2. Superconducting nanowire memory element
based on fluxoid (vortex) trapping
Device 7715s1.
Wires patterned by carbon-
nanotube “molecular
templating”.
Device 82915s2.
Wires patterned by
electron-beam (e-beam)
lithography.
A. Murphy, D. Averin, and A. Bezryadin, New J. Phys. 19, 063015 (2017)
Superconductor film (Mo75Ge25)
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Switching current versus magnetic field:
Multi-valued Little-Parks oscillations
A. Murphy, D. Averin, and A. Bezryadin, New J. Phys. 19, 063015 (2017).
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Writing and reading bits of information (7715s1)
A. Murphy, D. Averin, and A. Bezryadin, New J. Phys. 19, 063015 (2017)
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Testing write-read cycle fidelity (7715s1)
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Transmon Qubit
Diagram courtesy C. Dickel
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Meissner Qubit in Cu 3D cavity
Vortices (i.e., their cores)
Design of the cavity is similar to:
H. Paik et al., Phys. Rev. Lett. 107, 240501 (2011)
J. Ku,
Z.Yoscovits,
A. Levchenko,
J. Eckstein,
A. Bezryadin
Phys. Rev. B 94, 165128
(2016)
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Examples quantum time-domain oscillation:
Ramsey fringe
J. Ku,
Z.Yoscovits,
A. Levchenko,
J. Eckstein,
A. Bezryadin
Phys. Rev. B 94, 165128
(2016)
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Conclusions
- Superconductivity is fun and can provide interesting technical solutions in various fields
- We detect thermal and quantum phase slips, which prove that the resistance is not exactly zero.
- We make a memory, a device which remember the number of induced phase slips
- We make qubits out of superconductors and detect radiation-free dissipation due to single vortices