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Superconductivity in Bismuth Oxide Compounds

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1 Superconductivity in Bismuth Oxide Compounds
Kitaoka Lab. Takashi MATSUMURA Mirza H. K. Rubel Angewandte Chemie International Edition Volume 53, Issue 14 B. A. Baumert Journal of Superconductivity, Vol. 8, No. 1, 1995 H. Matsuura and K. Miyake, J. Phys. Soc. Jpn. 81 (2012) R. A. Schweinfurth et al., Appl. Phys. Lett. 61 (1992)

2 Contents Introduction Bismuth oxide compounds Summary Superconductors
Bi-oxide compared with Cuprate Bismuth oxide compounds Ba 1−x K x Bi O 3 ( Na K 0.45 ) Ba 3 Bi 4 O 12 Summary

3 What is Superconductors
Zero resistivity Perfect diamagnetism Superconductivity is caused by formation of an electron pair. Introduction

4 History of Superconductors
1975 Tcmax~12K spin BaPbXBi1-XO3 1988 TCmax~30K Spin + orbital Ba1-XKXBiO3 phonon Introduction

5 High 𝑇 𝑐 Superconductors
Introduction

6 Bi-oxide compared with Cuprate
Ba 1−x K x Bi O 3 LaSrCuO 3D 2D Introduction

7 Bi-oxide compared with Cuprate
Energy Energy ? (6s)? (3d)9 (5d)10 Bi Cu Introduction

8 Valence skipping element Bi
[Xe](4f)14(5d)10 Bi4+ Bi4+ (6s) Energy (6 S) 0 (6 S) 1 (6 S) 2 Bi3+ Bi5+ Introduction

9 BaBiO3 Ba 2+ Bi 4+ Bi 3+ Bi 5+ / O 2− ×3 Ba 1−x K x Bi O 3

10 BaBiO3 In one dimension charge density wave(CDW) state q Bi5+ -2e Bi3+
Ba 1−x K x Bi O 3

11 Ba 1−x K x Bi O 3 Ba 2+ → K + (Hole Doping) Electron number is reduced

12 In one dimension Hole Doping ( Ba 2+ → K + )×2 Bi3+ Bi5+ Bi3+ Bi5+
Ba 1−x K x Bi O 3

13 In one dimension Hole Doping ( Ba 2+ → K + )×2 Bi3+ Bi5+ Bi5+ Bi5+
Ba 1−x K x Bi O 3

14 In one dimension Hole Doping ( Ba 2+ → K + )×2 Bi3+ Bi5+ Bi5+ Bi5+
Ba 1−x K x Bi O 3

15 K doping quantity vs 𝑇 𝑐 Superconductivity Ba 1−x K x Bi O 3

16 K doping quantity vs 𝑇 𝑐 C D W ? S C Ba 1−x K x Bi O 3

17 Crystal structure Bi3+ Bi5+ ( Ba 2+ → K + )×2 Ba 1−x K x Bi O 3

18 Crystal structure K concentration X x=0 x=0.04 x=0.4 Ba 1−x K x Bi O 3

19 Crystal structure x=0 x=0.04 x=0.4 Ba 1−x K x Bi O 3

20 After doping Bi3+ Bi5+ Ba 1−x K x Bi O 3

21 After doping Bi3+ Bi5+ Ba 1−x K x Bi O 3

22 After doping Bi5+ Bi3+ Ba 1−x K x Bi O 3

23 After doping Bi5+ Bi3+ Ba 1−x K x Bi O 3

24 Over doping Bi5+ Bi5+ Bi5+ Bi5+ Bi5+ Bi5+ No electron
Cannot be superconductor Ba 1−x K x Bi O 3

25 Average Bi valence vs 𝑇 𝑐
Average Bi valence is related to 𝑇 𝑐 ! Ba 1−x K x Bi O 3

26 ( Na 0.25 K 0.45 ) Ba 3 Bi 4 O 12 BaBi O 3 Ba 4 Bi 4 O 12
Double Perovskite structure ( Na K 0.45 ) Ba 3 Bi 4 O 12

27 ( Na 0.25 K 0.45 ) Ba 3 Bi 4 O 12 High 𝑇 𝑐 Superconductor

28 Average Bi valence vs 𝑇 𝑐
(BKBO) Similar Behavior!! ( Na K 0.45 ) Ba 3 Bi 4 O 12

29 Bi-oxide compounds’ 𝑇 𝑐

30 Bi-oxide compounds’ 𝑇 𝑐
( Na K 0.45 ) Ba 3 Bi 4 O 12 CDW

31 Summary The theoretical calculation suggests the novel superconductivity with high 𝑇 𝑐 in BKBO is mediated by the CDW fluctuation. It is suggested that ( Na K 0.45 ) Ba 3 Bi 4 O 12 has same superconductivity mechanism as BKBO.

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