Special Topics in Electrodynamics:

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Presentation transcript:

Special Topics in Electrodynamics: PHY 712 Electrodynamics 9-9:50 AM MWF Olin 105 Plan for Lecture 36: Special Topics in Electrodynamics: Electromagnetic aspects of superconductivity London equations Brief mention of quantum mechanism Tunneling between two superconductors 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

04/18/2018 PHY 712 Spring 2018 -- Lecture 36

04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Special topic: Electromagnetic properties of superconductors Ref:D. Teplitz, editor, Electromagnetism – paths to research, Plenum Press (1982); Chapter 1 written by Brian Schwartz and Sonia Frota-Pessoa History: 1908 H. Kamerlingh Onnes successfully liquified He 1911 H. Kamerlingh Onnes discovered that Hg at 4.2 K has vanishing resistance 1957 Theory of superconductivity by Bardeen, Cooper, and Schrieffer 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Behavior of superconducting material – exclusion of magnetic field according to the London model lL x 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Behavior of magnetic field lines near superconductor normal state: superconducting state: 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

04/18/2018 PHY 712 Spring 2018 -- Lecture 36

characteristic phonon energy density of electron states at EF attraction potential between electron pairs 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Temperature dependence of critical field From PR 108, 1175 (1957) Bardeen, Cooper, and Schrieffer, “Theory of Superconductivity” characteristic phonon energy density of electron states at EF attraction potential between electron pairs 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Type I superconductors: 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Type II superconductors 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Quantization of current flux associated with the superconducting state (Ref: Ashcroft and Mermin, Solid State Physics) 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Such “vortex” fields can exist within type II superconductors. Quantization of current flux associated with the superconducting state -- continued Suppose a superconducting material has a cylindrical void. Evaluate the integral of the current in a closed path within the superconductor containing the void. dl Such “vortex” fields can exist within type II superconductors. 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Crystal structure of one of the high temperature superconductors 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Some details of single vortex in type II superconductor 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Scanning probe images of vortices in YBCO at 22 K 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Mechanism for vortex detection -- Josephson junction -- tunneling current between two superconductors (Ref. Teplitz, Electromagnetism (1982)) d x Bz 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued Supercon left Junction Supercon right Bz d 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued Supercon left Junction Supercon right Ay d 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued d L R x Coupling parameter 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued JL JR JT L R x 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued JL JR JT L R x 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued JL JR JT L R x 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued Supercon left Junction Supercon right Ay d 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued JL JR JT L R x Bz 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued JL JR JT L R w w x 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued JL JR JT L R w w x 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued d JL JR JT L R w w x Bz 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Josephson junction -- continued SQUID =superconducting quantum interference device IT F/F0 Note: This very sensitive “SQUID” technology has been used in scanning probe techniques. See for example, J. R. Kirtley, Rep. Prog. Physics 73, 126501 (2010). 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

Scanning SQIUD microscopy Ref. J. R. Kirtley, Rep. Prog. Phys. 73 126501 (2010) 04/18/2018 PHY 712 Spring 2018 -- Lecture 36

04/18/2018 PHY 712 Spring 2018 -- Lecture 36

pg. 481 04/18/2018 PHY 712 Spring 2018 -- Lecture 36