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Superconductivityand
Low TemperaturePhysics II
Lecture NotesSummer Semester 2015
R. Gross© Walther-Meißner-Institute
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)General Remarks on the Courses to the Field
Superconductivity and Low Temperature Physics
The following lectures are offered on a regular basis:
1. Superconductivity and Low Temperature Physics I Foundations of Superconductivity
2. Superconductivity and Low Temperature Physics II (SS 2015: Thu., 12:30h, HS 3) Foundations of Low Temperature Physics and Techniques
3. Applied Superconductivity (SS 2015: Mon. & Wed., 14:15h, WMI) Josephson-Effects, Superconducting Electronics, Quantum Circuits
4. Several Seminars (see announcements)
Documents and Hints:http://www.wmi.badw.de Teaching (announcement of lectures) Lecture Notes (download of scripts, handouts, etc.) Seminars (announcement of seminars)
SS 2015:- Advances in Solid-State Physics
Tue. 10:15 – 11:30hSeminar room 143, WMI
- Superconducting Quantum CircuitsTue. 14:30 – 16:00hLibrary, WMI
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Applied SuperconductivitySuperconductivity andLow Temperature PhysicsII
Spin Electronics
Sum
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01
5VO,ÜB,
Skript
Seminar: Superconducting Quantum Circuits
Tue., 14.30 – 16.00 h, Seminar room, WMI
Seminar: Advances in Solid State Physics
Tue., 10.15 – 11.45 h, Seminar room, WMI
Seminar: Topical Issues in Magneto- and Spin Electronics
Wed., 10.15 – 11.45 hSeminar room, WMI
Mon. and Wed., 14.15 – 15.45 hSeminar room, WMI
Tue, 13.30 – 15.00 hSeminar room, WMI
VO,ÜB,
Skript
VO,ÜB,
Skript
Rudolf Gross Frank Deppe
Thu, 12.30 – 14.00 hPhysics Department, HS3
Hans Hübl
M. Althammer
Walther-Meißner-Institut (www.wmi.badw.de)
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year name discovery
1913 Heike Kamerlingh Onnes "For his investigations on the properties of matter at low temperatures which led, inter alia, to the production of liquid helium"
1972 John Bardeen, Leon Neil Cooper und Robert Schrieffer
"for their jointly developed theory of superconductivity, usually called the BCS-theory"
1973 Brian David Josephson "for his theoretical predictions of the properties of a supercurrent through a tunnel barrier, in particular those phenomena which are generally known as the Josephson effect"
1978 Pjotr Kapiza "for his basic inventions and discoveries in the area of low-temperature physics"
1985 Klaus von Klitzing "for the discovery of the quantized Hall effect"
1987 Johannes Georg Bednorz undKarl Alex Müller
"for their important break-through in the discovery of superconductivity in ceramicmaterials"
1996 David M. Lee, Douglas D. Osheroff und Robert C. Richardson
"for their discovery of superfluidity in helium-3"
1997 Steven Chu, Claude Cohen-Tannoudjiund William D. Phillips
"for development of methods to cool and trap atoms with laser light" See Laser cooling.
1998 Robert B. Laughlin, Horst Ludwig Störmer und Daniel Chee Tsui
"for their discovery of a new form of quantum fluid with fractionally charged excitations". See Quantum Hall effect.
2001 Eric A. Cornell, Wolfgang Ketterle und Carl E. Wieman
"for the achievement of Bose-Einstein condensation in dilute gases of alkali atoms, and for early fundamental studies of the properties of the condensates"
2003 Alexei Abrikosov, Witali Ginsburg und Anthony James Leggett
"for pioneering contributions to the theory of superconductors and superfluids"
Nobel Prizes in Physics related to low temperature physics
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Superconductivityand
Low TemperaturePhysics II
Contents of the Lecture
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I.1 Foundations and General PropertiesI.1.1 Quantum FluidsI.1.2 HeliumI.1.3 Van der Waals BondingI.1.4 Zero-Point FluctuationsI.1.5 Helium under PressureI.1.6 pT-Phase Diagram of 4He and 3HeI.1.7 Characteristic Properties of 4He and 3HeI.1.8 Specific Heat of 4He and 3He
I.2 4He as an Ideal Bose GasI.2.1 Bose-Einstein CondensationI.2.2 Bose-Einstein Condensation of 4He
I.3 Superfluid 4HeI.3.1 Experimental ObservationsI.3.2 Two-Fluid ModelI.3.3 Excitation Spectrum of 4He
I.4 VorticesI.4.1 Quantization of CirculationI.4.2 Experimental Study of Vortices
Contents Part I: Quantum Fluids
I.5 3HeI.5.1 normal fluid 3HeI.5.2 solid 3He and Pomeranchuk
effectI.5.3 superfluid 3He
I.6 3He / 4He mixtures
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II.1 Specific HeatII.1.1
II.2 Thermal ConductanceII.2.1
II.3 Phonons and ElectronsII.3.1
II.4 Magnetic Moments II.4.1
Contents Part II: Solids at Low Temperature
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III.1 IntroductionIII.1.1 General RemarksIII.1.2 Mesoscopic SystemsIII.1.3 Characteristic Length ScalesIII.1.4 Characteristic Energy ScalesIII.1.5 Transport Regimes
III.2 Description of Electron Transport by Scattering of WavesIII.2.1 Electron Waves and WaveguidesIII.2.2 Landauer FormalismIII.2.3 Multi-terminal Conductors
III.3 Quantum Interference EffectsIII.3.1 Double Slit ExperimentIII.3.2 Two Barriers – Resonant TunnelingIII.3.3 Aharonov-Bohm EffectIII.3.4 Weak LocalizationIII.3.5 Universal Conductance Fluctuations
III.4 From Quantum Mechanics to Ohm‘s Law
III.5 Coulomb Blockade
Contents Part III: Quantum Transport in Nanostructures
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IV.1 Generation of Low TemperaturesIV.1.1 IntroductionIV.1.2 Expansion MachineIV.1.3 Regenerative MachineIV.1.4 Joule-Thomson CoolingIV.1.5 SummaryIV.1.6 Evaporation CoolingIV.1.7 Dilution CoolingIV.1.8 Pomeranchuk CoolingIV.1.9 Adiabatic Demagnetization
IV.2 ThermometryIV.2.1 IntroductionIV.2.2 Primary ThermometersIV.2.3 Secondary Thermometers
Contents Part IV: Cryogenic Techniques:
Generation and Measurement of LT
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• F. PobellMatter and Methods at Low Temperatures, Springer 1996
• D.R. Tilley and J. TilleySuperfluidity and Superconductivity, Adam Hilger 1990
• C. Enss and S. HunklingerLow-Temperature Physics, Springer 2005
• P.V.E. McClintock, D.J. Meredith, J.K. WigmoreMatter at Low Temperatures, Blackie 1984
• J. Wilks, D.S. BettsIntroduction to Liquid Helium, Oxford 1987
• A. KentExperimental Low Temperarure Physics, MacMillan, New York
• G.K. White, P.J. MeesonExperimental Techniques in Low Temperature PhysicsOxford University Press, 2002
• K.H. Bennemann, J.B. KettersonThe Physics of Liquid and Solid Helium I and II, Wiley 1978
• H. Frey, R.A. HaeferTieftemperaturtechnologie, VDI-Verlag, Düsseldorf 1981
• Yoseph ImryIntroduction to Mesoscopic PhysicsOxford University Press, Oxford (1997)
• Supriyoto DattaElectronic Transport in Mesoscopic SystemsCambridge University Press, Cambridge (1995)
• Thomas HeinzelMesoscopic Electronic in Solid State NanostructuresWiley VCH, Weinheim (2003)
Literature
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) •superconductivity and superfluidity
•magnetism
•mesoscopic physics
•nanoscale superconducting and spintronic devices
•superconducting quantum bits
•………
an appetizer
Low Temperature Physics at WMI
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25 nm
Nb Au
Flux Qubit WMI
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Pr1.85Ce0.15CuO4
Crystal Growth Lab
YBa2Cu3O7-d
Bi2Sr2CaCu2O8+d Image Furnace
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fiber for IR laser heating
substrate manipulators
excimer laser optics
target manipulators
pyrometer
casing of RHEED screen and camera
operator tool
AFM/STM system
atomic oxygen source
Laser-Molecular Beam Epitaxy
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[1] R. Gross et al., SPIE Conf. Proc. Vol. 4058 (2000), pp. 278-294
[2] J. Klein, C. Höfener, L. Alff, and R.Gross, Supercond. Sci. Technol. 12, 1023 (1999).
[3] J. Klein, C. Höfener, L. Alff, and R.Gross, J. Magn. and Magn. Mat. 211, 9 (2000).
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SrTiO3
La2/3Ba1/3MnO3
Oxide Heterostructures for Oxide Electronics
Example: Magnetic Tunnel Junction for
Magnetic Random Access Memories (MRAM)
SrTiO3
La2/3Ba1/3MnO3
La2/3Ba1/3MnO3
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Clean Room: 50m², class 100
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Electron Beam Lithography
Philips XL30 SFEG
Lithography System:
Raith ELPHY plus
Al
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Intel dual-core 45 nm
(2007)
first transistor (1947)
Bardeen, Brattain, & Shockley
vacuum tubes
ENIAC (1946)
Enigma (1940)
physics
technology
superconducting Qubit
20 µm
WMI
From mechanical to quantum mechanical IP
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Collaborative Research Center 631 Cluster of Excellence NIM
CeNS
F
WSI
F
SemiconductorQuantum Dots
MPQ
Trapped Atoms and Ions
2 µm
Al
WMI
Superconducting Qubits
Development of Hardware Platform for QIP Systems
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mK Technology for Circuit QED Experiments
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mK Technology for Circuit QED Experiments
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„Dry“ dilution refrigerator (~ 20 mK)
commercial exploitation by Vericold GmbH, Ismaning
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30
innovative cryoengineering
…..WMI develops first dry dilution fridge
K. Uhlig, Cryogenics 42, 73 – 77 (2002)
Oxford Instruments Triton family
market share of dry dilution fridges: > 90%
„Dry“ dilution refrigerator (~ 20 mK)
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WMI Quantum Science Laboratory
Dezember 2011
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Helium-Liquefaction
• Helium liquefier at WMI:Linde TCF 20
• supply of LHe to both MunichUniversities
• liquefaction power: > 150 000 l/year
• market price:about 1 Mio. €
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SomeIntroductory
Remarks
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Temperature Scale
10-7
10-6
10-5
10-4
10-3
10-2
10-1
100
101
102
103
104
105
106
107
108
109
tem
per
atu
re (
K)
same amount of new physicson every decade of log T scale
center of hottest stars
center of the sun, nuclear energies
electronic energies, chemical bonding
surface of sun, highest boiling temperatures
organic life
liquid air
liquid 4Heuniverse
superfluid 3He
lowest temperatures of condensed matter
elec
tro
nic
m
ag
net
ism
nu
clea
r-m
ag
net
ism
sup
erco
nd
uct
ivit
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low
te
mp
era
ture
re
se
arc
h
lowest temperature in nuclear spin system achieved by adiabatic demagnetizationof Rhodium nuclei: ≈ 100 pK
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Year
low
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tem
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paramagnetic refrigeration
nuclear demagnetization
Generation of Low Temperatures - History
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Carl Paul Gottfried von Linde* 11. Juni 1842 in Berndorf, Oberfranken
† 16. November 1934 in Munich
Low Temperature Technology in Germany
1868 offer of chair at thePolytechnische Schule München (now TUM)
1873 development of cooling machine allowingthe temperature stabilization in beer brewing
21. 6. 1879 foundation of „Gesellschaft für Linde’sEismaschinen AG“ together with twobeer brewers and three other co-founders
1892 - 1910 re-establishment of professorship
12.5.1903 patent application: „Lindesches Gegenstrom-verfahren“liquefaction of oxygen(-182°C = 90 K)
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Walther Meißner* 16. Dezember 1882 in Berlin
† 15. November 1974 in Munich
1913 – 1934 building and heading of low temperaturelaboratory at the Physikalisch-Technischen-Reichsanstalt, liquefaction of H2 (20K)
7.3.1925 first liquefaction of He in Germany (4.2 K, 200 ml), 3rd system world-widebesides Leiden and Toronto
1933 discovery of perfect diamagnetism ofsuperconductors together with OchsenfeldMeißner-Ochsenfeld Effect
1934 offer of chair at theTechnische Hochschule München (now TUM)
1946 – 1950 president of the Bayerischen Akademie der Wissenschaften
1946 foundation of the commission for Low Temperature Research Walther-Meißner-Institut
Walther Meißner - der Mann, mit dem die Kälte kamW. Buck, D. Einzel, R. Gross, Physik Journal, Mai 2013
Low Temperature Technology in Germany