Presentation is loading. Please wait.

Presentation is loading. Please wait.

A new type Iron-based superconductor ~K 0.8 Fe 2-y Se 2 ~ Kitaoka lab Keisuke Yamamoto D.A.Torchetti et al, PHYSICAL REVIEW B 83, 104508 (2011) W.Bao et.

Published byCory Marsh Modified over 8 years ago

Similar presentations

Presentation on theme: "A new type Iron-based superconductor ~K 0.8 Fe 2-y Se 2 ~ Kitaoka lab Keisuke Yamamoto D.A.Torchetti et al, PHYSICAL REVIEW B 83, 104508 (2011) W.Bao et."— Presentation transcript:

1 A new type Iron-based superconductor ~K 0.8 Fe 2-y Se 2 ~ Kitaoka lab Keisuke Yamamoto D.A.Torchetti et al, PHYSICAL REVIEW B 83, 104508 (2011) W.Bao et al, arXiv:1102.0830v1 Feb (2011)

2 Contents Introduction –Iron-based superconductor History Structure Characteristics Experiment ~K 0.8 Fe 2-y Se 2 ~ –Comparison to previous sample –NMR measurement Summary 2

3 History of superconductivity under high pressure 0 50 100 150 200 SmO 0.9 F 0.11 FeAs LaO 0.89 F 0.11 FeAs LaOFeP Hg-Ba-Ca-Cu-O () Tl-Ba-Ca-Cu-O Bi-Sr-Ca-Cu-O Y-Ba-Cu-O MgB 2 NbGe NbN NbC Nb Pb high-T c cuprate metal iron-based system Transition temperature (K) 1900192019401960198020002020 Year Hg La-Ba-Cu-O Discovery of superconducting phenomenon 1911 1986 High-T c cuprate superconductor 2006 Iron-based high-T c superconductor 77 163 1979 Heavy fermion superconductor CeCu 2 Si 2 heavy fermion system PuCoGa 5 Introduction 3

4 Iron-based superconductor LaFeAsOBaFe 2 As 2 LiFeAs FeSe Fe As Se 1111 system122 system 111 system 11 system T c max = 55K T c max = 38K T c max = 18K T c max = 8K Fe-Pnictide layer Introduction Pnictgen(15 族元素 ) 4

5 Iron-based superconductor Introduction Band structure Fermi suface Phase diagram 5 hole electron nesting hole electron

6 Iron-based superconductor FeSe Dy Pr Ce La Er Ba Na Li Nd Regular tetrahedron(109.5°) Anion height α Fe Pnictgen 6 Introduction

7 K 0.8 Fe 2-y Se 2 Characteristics isostructural to BaFe 2 As 2 relatively high T c of ~33K heavily electron-doped system Introduction Cs 0.8 K 0.8 Cs 0.8 FeSe Dy Pr Ce La Er Ba Na Li Nd Regular tetrahedron(109.5°) TCTC TNTN TSTS 1111~55K~140K~155K 122~38K~135K~140K K 0.8 Fe 2-y Se 2 ~33K~560K~580K 7 J.Guo et al, PHYSICAL REVIEW B 82, 180520R 2010

8 Fermi surface Experiment Previous superconductor K 0.8 Fe 2-y Se 2 8 Qian et al, arXiv:1012.6017v1 Dec (2010) Band structure Fermi suface Band structure Fermi suface hole electron nesting hole electron hole electron Absence of the hole band

9 Phase diagram Experiment Previous superconductor AFM:antiferromagnetic ( 反強磁性 ) SDW:spin density wave ( スピン密度波 ) M.Fang et al, EPL, 94 (2011) 27009 9 T S,T N ≒ 140K~160K T cMAX ≒ 50K T S,T N ≒ 300K ~ 500K T cMAX ≒ 33K Expect higher T c K 0.8 Fe 2-y Se 2

10 M~3.31μ B Ordered state Experiment Previous superconductor Stripe magnetic order Orthorhombic (斜方晶) unusual antiferromagnetic structure Tetragonal (正方晶) Fe vacancy order M~0.5μ B 10 Fe As W.Bao et al, arXiv:1102.0830v1 Feb (2011) K 0.8 Fe 2-y Se 2

11 Electron-dope Experiment D.A.Torchetti et al, PHYSICAL REVIEW B 83, 104508 (2011) E DOS E F0 ~ k B T ( large ) High temperature E DOS E F0 ~ k B T ( small ) Low temperature Similar to the electron-doped systems among Fe-based superconductors K 0.8 Fe 2-y Se 2 DOS : density of states 11

12 Lack the hole bands near the zone center AFSF (antiferromagnetic spin fluctuation) 1/T 1 T is enhanced toward Tc in both FeSe and the optimally doped Ba(Fe 0.92 Co 0.08 ) 2 As 2 enhancement of the AFSF K x Fe 2-y Se 2 Ba122(OVD) Experiment D.A.Torchetti et al, PHYSICAL REVIEW B 83, 104508 (2011) TcTc In K 0.8 Fe 2 Se 2, there is no enhancement similarly to overdoped, nonsuperconducting Ba(Fe 0.86 Co 0.14 ) 2 As 2 TcTc (T c ~25K) (T c ~0K) (T c ~33K) (T c ~9K) TcTc 12 FeSe Ba122(OPT) nesting hole electron Electron dope

13 Summary Introduction about K 0.8 Fe 2-y Se 2 What is the reason of relatively high T c ? –The structure of Fe-pnictide layer ? –Nesting between electron-band and hole- band ? –High T N and T s ? This sample gives us a new point of view about Iron-based superconductors 13

14 14

15 15

16 16 R.Liu et al, EPL, 94 (2011) 27008

17 17

18 NMR spectrum NMR Intensity H Introduction Zeeman interaction m=+1/2 m=-1/2  ℏ H 0 Zeeman splitting μ : moment of nuclear spin( 核磁気モーメント ) γ : nuclear gyromagnetic ratio( 核磁気回転比 )

19 Knight shift NMR Intensity H electron Introduction

20 Nuclear spin-lattice relaxation time T 1 thermal equilibrium state excited state Electron system Lattice system Nuclear spin-lattice relaxation time( 核スピン格子緩和時間 ) Exchange of energy thermal equilibrium state T1T1

21 H.Kotegawa et al, arXiv:1101.4572v4 12 Apr 2011D.A.Torchetti et al, PHYSICAL REVIEW B 83, 104508 (2011) 1/T 1

22 1/T 1 T Experiment H.Kotegawa et al, arXiv:1101.4572v4 12 Apr 2011 FeSe (Fe 0.9 Co 0.1 )Se electron dope doping suppresses the AFSF and SC K 0.8 Fe 2 Se 2 character of the band near the Fermi level is different form FeSe H.Ikeda et al, JPSJ.77.123707 (2008)

23 77 K vs 1/T 1 T Experiment H.Kotegawa et al, arXiv:1101.4572v4 12 Apr 2011 Korringa relation κ << 1 κ >> 1 ferromagneticantiferromagnetic K orb =0.02% A hf χ spin (T =0)=0 The non linear relationship κ is not very far from 1 the increase toward low temperature Spin correlations are not so strong, but AF spin correlations are developed κ : korringa ratio( コリンハ比率 )

Download ppt "A new type Iron-based superconductor ~K 0.8 Fe 2-y Se 2 ~ Kitaoka lab Keisuke Yamamoto D.A.Torchetti et al, PHYSICAL REVIEW B 83, 104508 (2011) W.Bao et."

Similar presentations

Magnetic-field-induced charge-stripe order in the high-temperature superconductor YBa2Cu3Oy Tao Wu et. al. Nature 477, 191 (2011). Kitaoka Lab. Takuya.

Magnetic-field-induced charge-stripe order in the high-temperature superconductor YBa2Cu3Oy Tao Wu et. al. Nature 477, 191 (2011). Kitaoka Lab. Takuya.
Progress in the study of high T c electron doped Ca 10 (Pt 3 As 8 )(Fe 2 As 2 ) 5 and Ca 10 (Pt 4 As 8 )(Fe 2 As 2 ) 5 superconductors Ni University of.

Progress in the study of high T c electron doped Ca 10 (Pt 3 As 8 )(Fe 2 As 2 ) 5 and Ca 10 (Pt 4 As 8 )(Fe 2 As 2 ) 5 superconductors Ni University of.
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.
A new class of high temperature superconductors: “Iron pnictides” Belén Valenzuela Instituto de Ciencias Materiales de Madrid (ICMM-CSIC) In collaboration.

A new class of high temperature superconductors: “Iron pnictides” Belén Valenzuela Instituto de Ciencias Materiales de Madrid (ICMM-CSIC) In collaboration.
Iron pnictides: correlated multiorbital systems Belén Valenzuela Instituto de Ciencia de Materiales de Madrid (ICMM-CSIC) ATOMS 2014, Bariloche Maria José.

Iron pnictides: correlated multiorbital systems Belén Valenzuela Instituto de Ciencia de Materiales de Madrid (ICMM-CSIC) ATOMS 2014, Bariloche Maria José.
NMR Studies of Metal-Insulator Transitions Leo Lamontagne MATRL286K December 10 th, 2014.

NMR Studies of Metal-Insulator Transitions Leo Lamontagne MATRL286K December 10 th, 2014.
Terahertz spectroscopy of electromagnons excitation in a hexaferrite Ba 2 Mg 2 Fe 12 O 22 Ashida Lab. Tadataka Saito Phy.Rev.B 83, 064422(2011) Phy.Rev.

Terahertz spectroscopy of electromagnons excitation in a hexaferrite Ba 2 Mg 2 Fe 12 O 22 Ashida Lab. Tadataka Saito Phy.Rev.B 83, (2011) Phy.Rev.
Kitaoka lab. Takayoshi SHIOTA M1 colloquium N. Fujiwara et al., Phys. Rev. Lett. 111, 097002 (2013) K. Suzuki et al., Phys. Rev. Lett. 113, 027002 (2014)

Kitaoka lab. Takayoshi SHIOTA M1 colloquium N. Fujiwara et al., Phys. Rev. Lett. 111, (2013) K. Suzuki et al., Phys. Rev. Lett. 113, (2014)
1 High Pressure Study on MgB 2 B.Lorenz, et al. Phys. Rev.B 64,012507(2001) Shimizu-group Naohiro Oki.

1 High Pressure Study on MgB 2 B.Lorenz, et al. Phys. Rev.B 64,012507(2001) Shimizu-group Naohiro Oki.
Yoshida Lab Tatsuo Kano 1.  Introduction Computational Materials Design First-principles calculation DFT(Density Functional Theory) LDA(Local Density.

Yoshida Lab Tatsuo Kano 1.  Introduction Computational Materials Design First-principles calculation DFT(Density Functional Theory) LDA(Local Density.
Study of Collective Modes in Stripes by Means of RPA E. Kaneshita, M. Ichioka, K. Machida 1. Introduction 3. Collective excitations in stripes Stripes.

Study of Collective Modes in Stripes by Means of RPA E. Kaneshita, M. Ichioka, K. Machida 1. Introduction 3. Collective excitations in stripes Stripes.
SDW Induced Charge Stripe Structure in FeTe

SDW Induced Charge Stripe Structure in FeTe
Recap: U(1) slave-boson formulation of t-J model and mean field theory Mean field phase diagram LabelStateχΔb IFermi liquid≠ 0= 0≠ 0 IISpin gap≠ 0 = 0.

Recap: U(1) slave-boson formulation of t-J model and mean field theory Mean field phase diagram LabelStateχΔb IFermi liquid≠ 0= 0≠ 0 IISpin gap≠ 0 = 0.
The new iron-based superconductor Hao Hu The University of Tennessee Department of Physics and Astronomy, Knoxville Course: Advanced Solid State Physics.

The new iron-based superconductor Hao Hu The University of Tennessee Department of Physics and Astronomy, Knoxville Course: Advanced Solid State Physics.
 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)
Electronic structure of La2-xSrxCuO4 calculated by the

Electronic structure of La2-xSrxCuO4 calculated by the
Wendy Xu 286G 5/28/10.  Electrical resistivity goes to zero  Meissner effect: magnetic field is excluded from superconductor below critical temperature.

Wendy Xu 286G 5/28/10.  Electrical resistivity goes to zero  Meissner effect: magnetic field is excluded from superconductor below critical temperature.
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.
The Three Hallmarks of Superconductivity

The Three Hallmarks of Superconductivity
What Pins Stripes in La2-xBaxCuO4? Neutron Scattering Group

What Pins Stripes in La2-xBaxCuO4? Neutron Scattering Group

Similar presentations

Ads by Google