Presentation is loading. Please wait.

Presentation is loading. Please wait.

H.Sakakibara et al., PRB-85, 064501 (2012) H.Sakakibara et al., PRB-89, 224505 (2014) MORISHITA Naoki Kusakabe laboratory M1 Division of Frontier Materials.

Published byAlaina Nelson Modified over 9 years ago

Similar presentations

Presentation on theme: "H.Sakakibara et al., PRB-85, 064501 (2012) H.Sakakibara et al., PRB-89, 224505 (2014) MORISHITA Naoki Kusakabe laboratory M1 Division of Frontier Materials."— Presentation transcript:

1 H.Sakakibara et al., PRB-85, 064501 (2012) H.Sakakibara et al., PRB-89, 224505 (2014) MORISHITA Naoki Kusakabe laboratory M1 Division of Frontier Materials Science, Department of Material Engineering Science Graduate School of Engineering Science, Osaka University

2  Introduction ◦ Superconductivity and superconductors  Theoretical models and approaches ◦ Conventional Modeling: The Single-orbital Model ◦ New Modeling : The Two-orbital model ◦ Sakakibara’s Rule  Summary Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 2/15

3 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 3/15 Introduction Phenomena ・ zero resistivity ・ Meissner effect ・ pinning effect ・ Josephson effect Temperature ( K ) Resistivity ( Ω ) Applications ・ power line ・ linear motor train ・ NMR/MRI ・ SQUID

4 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 4/15 Introduction Block layer(s) Buffer layer(s)

5 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 5/15 Introduction liquid nitrogen temperature 77(K)↓ 30(K) (1986) 90(K) (1987) 135(K) (1993) 153(K) (under high-pressure) (2013) 166(K)!? (under high-pressure) (2005) http://sakaki.issp.u-tokyo.ac.jp/user/kittaka/contents/others/tc-history.html

6 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 6/15 Theoretical models and approaches Wannierized wave functionWhole structure on the Cu-O plane Conventional Modeling

7  The Hubbard model(single-orbital) Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 7/15 Theoretical models and approaches 0.15 holes per site = optimal doping ( 最適ドープ ) Conventional Modeling We know much about superconductivity of this model.

8 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 8/15 Theoretical models and approaches H.Sakakibara et al., PRB-85, 064501 (2012) Conventional Modeling

9 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 9/15 Theoretical models and approaches ◆:Theory (single-orbital model) H.Sakakibara et al., PRB- 89, 224505(2014) 25 7575 100 50 ● ● Conventional Modeling

10 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 10/15 Theoretical models and approaches New Modeling H.Sakakibara et al., PRB-85, 064501 (2012)

11  Two-orbital model Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 11/15 Theoretical models and approaches Bad for S.C. / (^o^) \ Good for S.C. \ (^o^) / New Modeling

12 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 12/15 Theoretical models and approaches H.Sakakibara et al.,PRB- 89, 224505(2014) New Modeling

13 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 13/15 Theoretical models and approaches H.Sakakibara et al.,PRB- 89, 224505(2014) (a)Theory(b)Experiment New Modeling

14 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 14/15 Theoretical models and approaches Our aim Large(→bad nesting…)Small(→good nesting!)

15 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ. 15/15 Thank you for your kind attention!

16 Kusakabe lab., Graduate School of Engineering Science, Osaka Univ.

Download ppt "H.Sakakibara et al., PRB-85, 064501 (2012) H.Sakakibara et al., PRB-89, 224505 (2014) MORISHITA Naoki Kusakabe laboratory M1 Division of Frontier Materials."

Similar presentations

Inhomogeneous Superconductivity in the Heavy Fermion CeRhIn 5 Tuson Park Department of Physics, Sungkyunkwan University, Suwon 440-746, South Korea IOP.

Inhomogeneous Superconductivity in the Heavy Fermion CeRhIn 5 Tuson Park Department of Physics, Sungkyunkwan University, Suwon , South Korea IOP.
WHAT IS SUPERCONDUCTIVITY?? For some materials, the resistivity vanishes at some low temperature: they become superconducting. Superconductivity is the.

WHAT IS SUPERCONDUCTIVITY?? For some materials, the resistivity vanishes at some low temperature: they become superconducting. Superconductivity is the.
The DFT-calculation of Potassium doped Picene Kotaro Yamada Kusakabe labolatory.

The DFT-calculation of Potassium doped Picene Kotaro Yamada Kusakabe labolatory.
High T c Superconductors & QED 3 theory of the cuprates Tami Pereg-Barnea

High T c Superconductors & QED 3 theory of the cuprates Tami Pereg-Barnea
Superconductivity Michael Spreitzer. Overview „Superconductivity“ ? Who discovered it ? Meissner & Ochsenknecht effect? BCS – Theory Different types of.

Superconductivity Michael Spreitzer. Overview „Superconductivity“ ? Who discovered it ? Meissner & Ochsenknecht effect? BCS – Theory Different types of.
BiS 2 compounds: Properties, effective low- energy models and RPA results George Martins (Oakland University) Adriana Moreo (Oak Ridge and Univ. Tennessee)

BiS 2 compounds: Properties, effective low- energy models and RPA results George Martins (Oakland University) Adriana Moreo (Oak Ridge and Univ. Tennessee)
Kitaoka lab Itohara Keita

Kitaoka lab Itohara Keita
Oda Migaku STM/STS studies on the inhomogeneous PG, electronic charge order and effective SC gap of high-T c cuprate Bi 2 Sr 2 CaCu 2 O 8+  NDSN2009 Nagoya.

Oda Migaku STM/STS studies on the inhomogeneous PG, electronic charge order and effective SC gap of high-T c cuprate Bi 2 Sr 2 CaCu 2 O 8+  NDSN2009 Nagoya.
Kitaoka Lab. M1 Yusuke Yanai Wei-Qiang Chen et al., EPL, 98 (2012) 57005.

Kitaoka Lab. M1 Yusuke Yanai Wei-Qiang Chen et al., EPL, 98 (2012)
Superconducting Quantum Interference Device SQUID C. P. Sun Department of Physics National Sun Yat Sen University.

Superconducting Quantum Interference Device SQUID C. P. Sun Department of Physics National Sun Yat Sen University.
 Single crystals of YBCO: P. Lejay (Grenoble), D. Colson, A. Forget (SPEC)  Electron irradiation Laboratoire des Solides Irradiés (Ecole Polytechnique)

 Single crystals of YBCO: P. Lejay (Grenoble), D. Colson, A. Forget (SPEC)  Electron irradiation Laboratoire des Solides Irradiés (Ecole Polytechnique)
Doping and Disorder in the Oxygenated, Electron-doped High-temperature Superconductor Pr 2-x Ce x CuO 4±  The building blocks of the high-temperature.

Doping and Disorder in the Oxygenated, Electron-doped High-temperature Superconductor Pr 2-x Ce x CuO 4±  The building blocks of the high-temperature.
Search for high temperature superconductivity of Sr 2 VO 4 under high pressure Shimizu Lab Kaide Naohiro.

Search for high temperature superconductivity of Sr 2 VO 4 under high pressure Shimizu Lab Kaide Naohiro.
Doped Semiconductors Group IVA semiconductors can be “doped” by adding small amounts of impurities with more or fewer than 4 valence electrons. e.g. add.

Doped Semiconductors Group IVA semiconductors can be “doped” by adding small amounts of impurities with more or fewer than 4 valence electrons. e.g. add.
High Temperature Superconductivity: The Secret Life of Electrons in Cuprate Oxides.

High Temperature Superconductivity: The Secret Life of Electrons in Cuprate Oxides.
Free electrons – or simple metals Isolated atom – or good insulator From Isolation to Interaction Rock Salt Sodium Electron (“Bloch”) waves Localised electrons.

Free electrons – or simple metals Isolated atom – or good insulator From Isolation to Interaction Rock Salt Sodium Electron (“Bloch”) waves Localised electrons.
SQUID Based Quantum Bits James McNulty. What’s a SQUID? Superconducting Quantum Interference Device.

SQUID Based Quantum Bits James McNulty. What’s a SQUID? Superconducting Quantum Interference Device.
High Temperature Copper Oxide Superconductors: Properties, Theory and Applications in Society Presented by Thomas Hines in partial fulfillment of Physics.

High Temperature Copper Oxide Superconductors: Properties, Theory and Applications in Society Presented by Thomas Hines in partial fulfillment of Physics.
A1- What is the pairing mechanism leading to / responsible for high T c superconductivity ? A2- What is the pairing mechanism in the cuprates ? What would.

A1- What is the pairing mechanism leading to / responsible for high T c superconductivity ? A2- What is the pairing mechanism in the cuprates ? What would.
Hall Effect in Sr 14−x Ca x Cu 24 O 41 E. Tafra 1, B. Korin-Hamzić 2, M. Basletić 1, A. Hamzić 1, M. Dressel 3, J. Akimitsu 4 1.Department of Physics,

Hall Effect in Sr 14−x Ca x Cu 24 O 41 E. Tafra 1, B. Korin-Hamzić 2, M. Basletić 1, A. Hamzić 1, M. Dressel 3, J. Akimitsu 4 1.Department of Physics,

Similar presentations

Ads by Google