Superconductivity in Zigzag CuO Chains

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Presentation transcript:

Superconductivity in Zigzag CuO Chains Erez Berg, Steven A. Kivelson Stanford University

Outline Pr2Ba4Cu7O15-: A new superconductor Evidence for quasi 1D superconductivity The theoretical model Phase diagram: from weak to strong coupling A possible mechanism of superconductivity: results from bosonizations and numerics (DMRG) Conclusions

Introduction to Pr2 Ba4Cu7O15- Structure: like the high Tc YBCO-247 CuO Plane CuO Single Chain Insulating and AF ordered! Structure like YBCO with Tc=110K However, transport properties are extremely different CuO Planes: essential for SC in YBCO, insulating and AF in PrBaCuO Single Chains Double chains Single crystal: very quasi 1d conductivity Single chains are disordered, double chains are conducting CuO Double Chain For single crystals: b/a1000

Superconductivity in Pr2 Ba4Cu7O15- [1] M. Matsukawa et al., Physica C 411 (2004) 101–106 [2] S. Sasaki et al., cond-mat/0603067 Upon oxygen reduction (>0), the material becomes superconducting at low T [1] An NQR experiment [2] shows evidence that the superconductivity occurs in the double chains =0 Superconductivity discovered by Y. Yamada’s group in Japan At delta=0, conductivity is metallic When delta is increased, superconductivity appears with a maximal Tc of about 15K at delta=0.45 The same group presented evidence that it is the double chains that are responsible for superconductivity They did Cu NQR, which is like NMR but you use the coupling of the Cu quadropole moments of the nuclei to local EFG instead of external magnetic fields This way you can distinguish between inequivalent copper sites in the lattice The found a sharp feature in 1/T1 vs T of the double chain coppers at Tc, but of no other copper site, which implies that that is where sc is occuring Why this problem is interesting? Because it’s a q1d superconductor, which we have chance to understand Because the zigzag chain appears in other materials =0.45 Tc15K

The Theoretical Model A single zigzag chain: Cu O

The Theoretical Model A single zigzag chain: + - d + _ py Cu O + _ px

Schematic Phase Diagram Recent results: Increasing  =0 Coupling Constant, U Phase seperation Super- conducting Q1D metal? CDW? 1. This is a schematic phase diagram. Explain the axis 2. The physical initial state and path for delta>0 3. What do we mean by superconductivity in 1d? 4. Weak coupling limit 5. Results on strong coupling Superconducting Doping, n “Half Filling”: one hole per copper

J2 is strongly frustrated! Strong Coupling Half Filling The charge degrees of freedom are gapped Effective spin interactions: J1 J2 Cu O J1>0 (AF) J2<0 (FM) J2 is strongly frustrated!

Strong Coupling Half Filling For this system, the spin gap is exponentially small exp(-const.|J1/ J2|) J1 Cu O J2 Affleck and White (1996) Itoi and Qin (2000)

Strong Coupling Finite Filling Doped holes are expected to go mostly into the oxygen orbitals A doped hole causes a  shift in the phase of AF fluctuations in its chain Cu O

Strong Coupling Doping can relieve the frustration: Finite Filling Relieving of the frustration is maximal if neighboring doped holes go into opposite chains!

Strong Coupling Doping can relieve the frustration: Finite Filling Relieving of the frustration is maximal if neighboring doped holes go into opposite chains!

Strong Coupling Doping can relieve the frustration: Finite Filling Relieving of the frustration is maximal if neighboring doped holes go into opposite chains!

Strong Coupling Finite Filling Minimum magnetic energy configuration: holes appear in alternating order in the two chains Magnetic energy gained: Em/L – s2 –|J2|2x2 (x is the doping) Kinetic energy cost of alternating order: Ek/L x3 The magnetic part wins for small x At low enough x, the system phase seperates!

Relation to Superconductivity? The “alternating phase” is good for superconductivity: The relative charge mode -,c is gapped with -,c x Enhanced pairing correlations The residual long-range interactions between doped holes are attractive Superconductivity occurs At low doping, where the charge Luttinger exponent K+,c uc becomes large:

DMRG Simulation System of length=80 Cu sites with doping x=0.25 Open Boundary Conditions

DMRG Simulation System of length=80 Cu sites with doping x=0.25 Spin/Charge density profiles near the edge of the system:

Conclusions In the new superconductor Pr2Ba4Cu7O15- there is evidence that superconductivity occurs in quasi-d zigzag CuO chains A model for a single zigzag CuO chain was studied by bosonization and DMRG From this model, we propose a possible mechanism of superconductivity Superconductivity is expected in a narrow region of doping near half filling

Spin Gap from DMRG