Abstract
In the traditional Bardeen–Cooper–Schrieffer theory of superconductivity, the amplitude for the propagation of a pair of electrons with momentum k and −k has a log singularity as the temperature decreases. This so-called Cooper instability arises from the presence of an electron Fermi sea. It means that an attractive interaction, no matter how weak, will eventually lead to a pairing instability. However, in the pseudogap regime of the cuprate superconductors, where parts of the Fermi surface are destroyed, this log singularity is suppressed, raising the question of how pairing occurs in the absence of a Fermi sea. Here we report Hubbard model numerical results and the analysis of angular-resolved photoemission experiments on a cuprate superconductor. In contrast to the traditional theory, we find that in the pseudogap regime the pairing instability arises from an increase in the strength of the spin–fluctuation pairing interaction as the temperature decreases rather than the Cooper log instability.
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Introduction
Evidence that the pseudogap (PG) in a slightly underdoped Bi2Sr2CaCu2O8+δ (Bi2212, Tc∼90 K) sample destroys the Bardeen–Cooper–Schrieffer (BCS) logarithmic pairing instability1 raises again the question of the role of the PG in the high-temperature superconducting cuprates2. The elimination of the BCS instability is consistent with the view that the PG competes with superconductivity. However, as noted in ref. 1, the onset of superconductivity with a Tc∼90 K suggests an alternative scenario in which the PG reflects the formation of short-range pairing correlations.
The superconducting transition temperature can be determined from the Bethe–Salpeter gap equation
Here G(k, ωn) is the dressed single-particle Green’s function, is the irreducible particle–particle pairing vertex, and k and ωn=(2n+1)πT are the usual momentum and Matsubara frequencies, respectively. The temperature at which the leading eigenvalue of equation (1) goes to 1 gives Tc and the corresponding eigenfunction φα(k, ωn) determines the symmetry of the gap. In spin–fluctuation theories, the pairing vertex is approximated by an effective interaction
with χ(q, ωm) the spin susceptibility and a coupling strength. Various groups have used experimental data to model χ(q, ωm), G(k, ωn) and , to determine whether a spin–fluctuation pairing interaction is consistent with the observed Tc values.
Dahm et al.3 used inelastic neutron scattering (INS) measurements for YBa2Cu3O6.6 to model the spin susceptibility χ(q, ωm) and a one-loop self-energy approximation to determine G. was an adjustable parameter estimated from INS and angular-resolved photoemission spectroscopy (ARPES) data. Using the resulting G and Veff in equation (1), they concluded that a spin–fluctuation interaction had sufficient strength to account for the observed Tc. Nishiyama et al.4 used INS results for χ(q, ω) and solved the Eliashberg equations for the heavy fermion compounds CeCuSi2 and CeIrIn3. For reasonable values of , they found Tc values, which were again consistent with the notion that antiferromagnetic (AF) spin fluctuations were responsible for pairing in these materials. In a recent paper, Mishra, et al.1 used ARPES data at T=140 K for a slightly underdoped Bi2212 (Tc=90 K) sample, to examine the effect of the PG on the superconducting transition temperature and to determine whether a spin–fluctuation pairing mechanism could account for the observed Tc. They found that the usual BCS logarithmic divergence associated with the propagators in equation (1) was destroyed by the PG and the leading eigenvalue λd(T) arising from the spin–fluctuation interaction (equation (2)) remained small, and was essentially independent of temperature. Thus, the question of the interplay between the PG and superconductivity2 continues to be of interest5,6,7,8.
Here we explore this question using numerical simulations for a Hubbard model and an analysis of ARPES data for a slightly underdoped Bi2212 sample in the superconducting state. The band parameters and filling of the Hubbard model are chosen so that it exhibits a PG as evidenced by a peak in the q=0 spin susceptibility, as the temperature decreases along with a gap, which opens in the antinodal region of the single-particle spectral weight A(k, ω). The ARPES data for Bi2212 was taken in the superconducting state at 40 K and provides a comparison with the previous analysis1 based on ARPES data taken in the normal state at 140 K. From the numerical calculations we conclude that the PG, similar to the superconductivity, arises due to short-range AF correlations, and that contrary to the usual case in which the pairing instability is associated with the Cooper instability, here the strength of the spin fluctuations increases as the temperature decreases, leading to the pairing instability. Our analysis of the 40 K Bi2212 ARPES data relative to the results of ref. 1, which were based on 140 K data on the same sample, shows an increase in the strength of the d-wave projection of the spin–fluctuation interaction strength, consistent with the dynamic cluster approximation (DCA) results. From this we conclude that contrary to the conclusion of ref. 1, spin fluctuations can account for the d-wave pairing in Bi2212.
Results
Underdoped Hubbard model with a PG
The two-dimensional Hubbard model we will consider has a near-neighbour hopping t, a next near-neighbour hopping t′/t=−0.15, an on-site Coulomb interaction U/t=7 and a filling 〈n〉=0.92. We will work in energy units where t=1. The DCA calculations9 were carried out on a 4 × 4 cluster and employed both continuous-time, auxiliary-field (CT-AUX) quantum Monte Carlo (QMC)10 and Hirsch-Fye (HF) QMC11 methods to solve the effective cluster problem. (The data in Figs 1, 2a and 3 were obtained with CT-AUX QMC and cross-checked with HF QMC. The equal-time data in Fig. 2b were obtained with HF QMC). (For more details, see Methods). In the DCA approximation, where depends only on a finite set of cluster momenta K, the k-sum in equation (1) gives12
Here Nc=16 is the cluster size and the pairing kernel G(k, ωn)G(−k, −ωn) has been coarse grained (averaged) over the momenta k′ of the DCA patches.
For the parameters we have chosen, the uniform static susceptibility χ(q=0, T) versus temperature, shown in Fig. 1a, exhibits a peak at T*=0.22 below which it decreases, as T is reduced13. This behaviour, seen in measurements of the magnetic susceptibility14 and Knight shifts15 of underdoped (hole) cuprates, reflects the opening of a PG. ARPES experiments16,17 find that this gap is anisotropic, opening in the antinodal regions of the Fermi surface. This behaviour has also been seen in DCA calculations of the single-particle spectral weight13,18. In Fig. 1b, the temperature dependence of the leading eigenvalue of the Bethe–Salpeter equation (3) is shown as the circles. Its eigenfunction has d-wave symmetry and λd(T) approaches 1 at low temperatures. Thus, this model system has a PG that opens below T* and a d-wave eigenvalue that increases towards 1 as T decreases.
In addition to suppressing the q=0 spin susceptibility, we find that the opening of the PG destroys the low-temperature BCS logarithmic divergence of the d-wave projection of the pairing kernel
Here, is defined in equation (4) and φd(K, ωn) is the d-wave eigenfunction, which is approximated as
with J∼4t2/U. A plot of P0,d(T) versus T is shown in Fig. 2a and one can see that below T*, P0,d(T) is suppressed as the PG opens19,20. Here we have normalized P0,d(T) to its value at a temperature T=0.5t above T*. For comparison, the solid squares in Fig. 2a show P0,d(T) for 〈n〉=0.85, which does not have a PG and one sees the usual BCS logarithmic behaviour (dashed curve).
The absence of the BCS divergence in P0,d(T) when there is a PG is consistent with the finding of Mishra et al.1. P0,d(T) is the d-wave projection of what Mishra et al.1 referred to as the pairing kernel.) However, as noted, they found that with this suppression, the spin–fluctuation pairing interaction failed to give a superconducting transition. Based on this, they suggested that the PG reflects the presence of short-range pairfield correlations, which grow below T* and become coherent at Tc. This behaviour could be likened to the magnetic response of the large U half-filled Hubbard model. In this case, the formation of local moments when the temperature drops below ∼U/2 is seen in an increase in the expectation value of the square of the local moment . In a similar way, one can look for the onset of local pair formation as T decreases below the PG temperature T*. Here, with and , we have calculated versus temperature. As shown in Fig. 1b, this correlation function does increase as the temperature decreases. However, the four near-neighbour pairfield correlations
contribute the dominant contribution to this increase as shown in Fig. 2b. These results suggest that the PG is more closely related to the formation of short-range AF correlations than to local pair correlations in agreement with earlier ideas of Johnston14 and more recent theoretical results5,6,7,8,21. This identification of the PG with the development of short-range AF spin correlations is also consistent with the increase of the spin susceptibility χ(q=(π, π), ωm=0) as shown in Fig. 3 and as seen experimentally22.
The spin–fluctuation pairing interaction
Returning to the question of whether the spin–fluctuation interaction (equation (2)) can lead to superconductivity when the logarithmic singularity of the BCS kernel is suppressed, we use DCA results for G(k, ωn) to construct Veff(q, ωm). Here, following Mishra et al.1, a random-phase approximation (RPA) form for χ is used
with
where is the DCA coarse-grained Green’s function (see Methods). The interaction in the denominator of equation (8) is estimated from the approximate fit of χRPA to χDCA shown in Fig. 3.
Next, replacing by Veff in equation (2) with the coupling set to and using DCA Green’s functions, we solve the Bethe–Salpeter equation (3). Results for λd(T) are shown (solid squares) in Fig. 1b. We conclude that the increase in the strength of the pairing interaction Veff leads to an increasing λd(T) similar to that which is found using determined from the DCA calculation. Thus, in spite of the absence of the BCS logarithmic increase in P0,d(T), we find that the increase in the strength of the spin fluctuations leads to an increase in λd(T) as the temperature is lowered.
This differs from the results of ref. 1, where ARPES data at T0=140 K was used to construct a single-particle A(k, ω, T0). Next, this spectral weight was used to approximate the single-particle propagator at lower temperatures T. In the Matsubara framework, this approximation is given by
with T0=140 K and ωn=(2n+1)πT. Using this approximation, they found that the pairing kernel P0,d(T) (equation (7)) was essentially independent of temperature as opposed to decreasing with temperature as seen in the DCA calculation (Fig. 2a). We believe that this reflects a failure of the approximation (equation (10)), and that to determine G(k, ωn) at a temperature T one needs the spectral weight at T0=T.
To further explore this question, we have used Bi2212 ARPES data taken at 40 K to construct G(k, ωn) at T=40 K. This data was used earlier to study the neutron resonance in the superconducting state in ref. 23. We have used the same procedure to extract the single-particle spectral weight A(k, ω) from the raw data as in ref. 23. However, as detailed in the following, the contribution of the Gorkov Green’s function F(k, ω) is estimated differently. Following ref. 1 we use an RPA form (equation (8)) for χ(q, ωm). At T=40 K, the system is superconducting so that
with F(k, ωn) the Gorkov Green’s function.
Here, Z(k, ωn) and X(k, ωn) are the even and odd parts of the ‘normal’ self-energy and φ(k, ωn) is the gap function. For the band dispersion ɛk, we used the ‘tb2’ tight-binding fit of ARPES data on Bi2212 given in ref. 24. The frequency dependence of X(k, ωn) was neglected and X(k, 0) was lumped into a shift of the chemical potential and the tight-binding band structure parameters. Here we will make the additional approximation
with ɛk/Z(k, ωn)=ɛk/Z0 and take Z0≈2 similar to ref. 1. In this case
As in refs 1, 23, the phenomenological parameter entering the spin susceptibility in equation (8) is determined by going to real frequencies and requiring that the Q=(π, π) spin resonance occurs at Ω∼40 meV. In our case, we find U≃500 meV.
With these approximations, we have calculated χ(q, ωm) at T=40 K. The d-wave projection of χ(q, ωm)
with gd(k)=cos kx−cos ky is plotted in Fig. 4. This figure also shows results obtained at T=140 K, as well as at 90 K, using A(k, ω, T=140 K). Similar to the results for the temperature dependence of the pairing kernel, there is little change in 〈χ(k−k′, ωm)〉d between 140 and 90 K based on A(k, ω, T=140 K). However, the T=40 K d-wave projection shows a clear increase in the strength of the spin fluctuations. We believe that if A(k, ω, T) spectral data were available for temperatures between 140 K and the superconducting transition temperature Tc∼90 K, one would see the strength of the d-wave projection 〈χ(k−k′, ωm)〉d increase, leading to an increase in the d-wave eigenvalue contrary to the results reported in ref. 1. One can of course ask whether the strength of the spin–fluctuation interaction at 40 K is sufficient to given an anti-nodal gap of order 50 meV. Using a value of the coupling constant of order of the bandwidth 1.5 eV, the solution of the Gorkov equation
using the spin–fluctuation interaction Veff(q, ωm) in equation (2) and the approximation equation (14) for F, is found to give an anti-nodal gap of 50 meV.
Discussion
We have used DCA calculations for an under (hole) doped 2D Hubbard model, which exhibits a PG, to see whether a spin–fluctuation interaction provides a reasonable approximation of the irreducible pairing interaction. In these calculations, the dynamic mean-field cluster is such that charge density and striping instabilities are suppressed, leaving AF and d-wave pairing as the dominant correlations. Although the PG eliminates the usual BCS logarithmic divergence of the pairing kernel, we find that a pairing instability arises from an increase in the strength of the spin–fluctuation interaction as the temperature decreases. The finding that the PG suppresses the BCS logarithmic divergence is similar to the result reported in ref. 1. However, the increase in the pairing strength of the spin fluctuations found in the DCA calculation is at odds with the results reported in ref. 1. We believe that this disagreement reflects a failure of the approximation in which the single-particle spectral weight at a higher temperature is used to determine the single-particle Green’s function at lower temperatures.
Using a single-particle spectral weight constructed from ARPES data at 40 K, we find a significant enhancement of the d-wave projected spin–fluctuation strength relative to that at 140 K. Thus, we find that the DCA results are consistent with the 40 K ARPES data and the increase in the strength of the spin fluctuations can lead to superconductivity.
Methods
Hubbard model
The 2D Hubbard model we consider in the numerical calculations is described by the Hamiltonian
Here, destroys (creates) an electron with spin σ on site i and is the corresponding number operator. The hopping tij has a near-neighbour amplitude t and a next-near-neighbour amplitude t′=−0.15t, leading to a dispersion
We use t=1 as the unit of energy and set the Coulomb repulsion U=7t.
Dynamic cluster approximation
To study the behaviour of the Hubbard model in equation (17), we use a DCA QMC algorithm9. Similar to finite-size lattice calculations, the DCA represents the bulk lattice by a finite-size cluster, but uses coarse graining to retain information about the bulk lattice degrees of freedom not represented on the cluster. This leads to an approximation of the thermodynamic limit, in which the bulk problem is replaced by a finite-size cluster embedded in a mean-field host that is designed to represent the rest of the system. The basic assumption is that correlations are short ranged and contained within the cluster, so that the self-energy Σ(k, iωn) is well approximated by a cluster self-energy Σ(K, iωn), where K are the cluster momenta. One then calculates a coarse-grained Green’s function
where μ is the chemical potential, which is tuned to give a fixed filling 〈n〉, and Nc is the number of sites in the cluster. For the 4 × 4 Nc=16 site clusters that we choose, the sum averages over the momenta k′ in a square patch centred at 0 with sides of length π/2. This reduces the complexity of the problem to that of a finite cluster of size Nc, which can be solved using QMC techniques. Here we use the CT-AUX quantum Monte Carlo algorithm developed by Gull et al.10 to calculate the self-energy as a functional of the cluster-excluded propagator and the interaction U.
Calculation of irreducible particle–particle vertex
In addition to the cluster single-particle Green’s function Gc(K, iωn), the QMC is also used to calculate the two-particle Green’s function in the singlet particle–particle channel with zero centre of mass momentum and energy, Gc,2(K, K′)≡Gc,2(K, −K, K′, −K′), where K=(K, iωn) and . The irreducible particle–particle vertex that enters in the DCA gap (equation (3)) is then extracted from the cluster Bethe–Salpeter equation
Data availability
The data that support the findings of this study are available from the corresponding author upon request.
Additional information
How to cite this article: Maier, T. A. et al. Pairing in a dry Fermi sea. Nat. Commun. 7:11875 doi: 10.1038/ncomms11875 (2016).
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Acknowledgements
We want to thank E. Gull, S. A. Kivelson, A.-M. Tremblay and L. Taillefer for useful comments. D.J.S. and T.A.M. acknowledge the support of the Center for Nanophase Materials Sciences, a US DOE Office of Science User Facility. Part of this research was sponsored by the Laboratory Directed Research and Development Program of Oak Ridge National Laboratory, managed by UT-Battelle, LLC, for the U.S. Department of Energy. U.C. acknowledges support from National Science Foundation under grant number DMR-1454304. An award of computer time was provided by the Innovative and Novel Computational Impact on Theory and Experiment (INCITE) programme. This research used resources of the Oak Ridge Leadership Computing Facility, which is a DOE Office of Science User Facility supported under Contract DE-AC05-00OR22725.
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D.S. and T.M. jointly conceived and designed the study. T.M. and P.S. performed the numerical calculations. U.C. and J.C. provided the experimental data, which V.M. analysed. All authors discussed the results and worked on the manuscript.
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Maier, T., Staar, P., Mishra, V. et al. Pairing in a dry Fermi sea. Nat Commun 7, 11875 (2016). https://doi.org/10.1038/ncomms11875
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DOI: https://doi.org/10.1038/ncomms11875
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