Three-dimensional flux states as a model for the pseudogap phase of transition metal oxides

Abstract: We propose that the pseudogap state observed in the transition metal oxides can be explained by a three-dimensional flux state, which exhibits spontaneously generated currents in its ground state due to electron-electron correlations. We compare the energy of the flux state to other classes of mean field states, and find that it is stabilized over a wide range of t and δ. The signature of the state will be peaks in the neutron diffraction spectra, the location and intensity of which are presented. The dependen… Show more

“…As expected from our analytical estimates in (6), if ∆U or t ⊥ gets too large, long-range order disappear as shown on Fig. 5.…”

“…the orbital antiferromagnetic phase (OAF), the staggered flux (SF) or the D-density wave (DDW) phase. In the context of high Tc superconductivity, these current carrying ground states have been proposed as competing states for the pseudogap phase [1,2,3,4,5,6]. The SF or the DDW phase has the attractive feature that the nodal quasi-particles have an energy spectrum similar to that of the d−wave superconducting state.…”

Current carrying ground state in a bilayer model of strongly correlated systems

“…As expected from our analytical estimates in (6), if ∆U or t ⊥ gets too large, long-range order disappear as shown on Fig. 5.…”

“…the orbital antiferromagnetic phase (OAF), the staggered flux (SF) or the D-density wave (DDW) phase. In the context of high Tc superconductivity, these current carrying ground states have been proposed as competing states for the pseudogap phase [1,2,3,4,5,6]. The SF or the DDW phase has the attractive feature that the nodal quasi-particles have an energy spectrum similar to that of the d−wave superconducting state.…”

Current carrying ground state in a bilayer model of strongly correlated systems

“…This causes the lack of periodic modulation of the spin and charge density. Such states have been proposed to describe the pseudogap phase of high T c superconductors 16,17,18 , the low temperature phase of α-(BEDT-TTF) 2 KHg(SCN) 4 19,20 , the antiferromagnetic phase in URu 2 Si 2 21,22 and other heavy fermion materials 23 , the charge density wave in 2H-TaSe 2 24 and the pseudogap phase in transition metal oxides 25 . Due to the wavevector dependence of the gap, the transition to this phase is metal to metal instead of metal to insulator, as in conventional density waves (with constant energy gap).…”

Large-Nlimit of a magnetic impurity in unconventional density waves

“…In fact, after the earlier proposals in the context of the excitonic insulator 2,3 , this topic was rediscovered in the early 90's in various dimensions and systems 4,5,6,7,8,9,10 . Since then, the realization of unconventional or nodal density waves 11,12 looks more and more possible: non-superconducting phase transitions without charge or spin ordering have been detected in a number of materials, and one of the possible explanations is provided by the unconventional density wave scenario 13,14,15,16 . One of the main reasons of interest on UDW arises from high T c superconductors, where one of the competing models in the pseudogap phase is the d-density wave state.…”

Impurity effects in unconventional density waves in the unitary limit