Doping and temperature evolution of pseudogap and spin-spin correlations in the two-dimensional Hubbard model

Kuz’min, V. I.; Visotin, Maxim A.; Николаев, С. В.; Овчинников, С. Г.

doi:10.1103/physrevb.101.115141

Cited by 13 publications

(8 citation statements)

References 97 publications

(133 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…More detailed analysis is planned in future work. Note that the similar effect has been recently observed for the temperature and doping evolution of the band structure in the Hubbard model [58,59]. When the chemical potential enters into the flat band and the quantum phase transition is observed, the density of states raises sharply [Fig.…”

Section: Polaron Band Structuresupporting

confidence: 75%

See 1 more Smart Citation

Polaron transformations in the realistic model of the strongly correlated electron system

et al. 2020

Self Cite

View full text Add to dashboard Cite

Electron-phonon coupling, diagonal in a real space formulation, leads to a polaron paradigm of smoothly varying properties. However, fundamental changes, namely the singular behavior of polarons, occur if offdiagonal pairing is involved into consideration. The study of polaron transformations and related properties of matter is of particular interest for realistic models, since competition between diagonal and off-diagonal electron-phonon contributions in the presence of other strong interactions can result in unconventional behavior of the system. Here we consider a two-dimensional multiband pd model of cuprate superconductors with electron-phonon interaction and analyze the features of the systems that are caused by the competition of diagonal and off-diagonal electron-phonon contributions in the limit of strong electron correlations. Using the polaronic version of the generalized tight-binding method, we describe the evolution of the band structure, Fermi surface, density of states at Fermi level, and phonon spectral function in the space of electron-phonon parameters ranging from weak to strong coupling strength of the adiabatic limit. On the phase diagram of polaron properties we reveal two quantum phase transitions and show how electron-phonon interaction gives rise to Fermi surface transformation (i) from hole pockets to true Fermi arcs and (ii) from hole to electron type of conductivity. We also demonstrate the emergence of new states in the phonon spectral function of the polaron and discuss their origin.

show abstract

Section: Polaron Band Structuresupporting

confidence: 75%

“…3(f) and 3(g)], and in the second, arcs are blurred and elongated to the boundaries of the Brillouin zone [Fig.4(b)]. In accordance with Ref [59],. we refer these states to the strong or weak pseudogap limit, respectively.…”

supporting

confidence: 84%

Polaron transformations in the realistic model of the strongly correlated electron system

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…After introducing the formalism and implementation of the CPT+DQMC method, we will explore three examples: the attractive Hubbard model in a superconducting state, the half-filled repulsive Hubbard model, and the doped repulsive Hubbard model. In these examples, we will illustrate the advantages of the DQMC solver over the standard ED solver for CPT [13,14,[16][17][18][19][20][21][22][23][24][25][26][27], and also demonstrate the advantages of the CPT+DQMC method over finite size DQMC simulations. We conclude with a brief discussion of interesting open problems that are particularly suitable for study by CPT+DQMC.…”

Section: Introductionmentioning

confidence: 99%

Determinantal Quantum Monte Carlo solver for Cluster Perturbation Theory

Huang¹,

Wang²

2021

Preprint

View full text Add to dashboard Cite

Cluster Perturbation Theory (CPT) is a technique for computing the spectral function of fermionic models with local interactions. By combining the solution of the model on a finite cluster with perturbation theory on intra-cluster hoppings, CPT provides access to single-particle properties with arbitrary momentum resolution while incurring low computational cost. Here, we introduce Determinantal Quantum Monte Carlo (DQMC) as a solver for CPT. Compared to the standard solver, exact diagonalization (ED), the DQMC solver reduces finite size effects through utilizing larger clusters, allows study of temperature dependence, and enables large-scale simulations of a greater set of models. We discuss the implementation of the DQMC solver for CPT and benchmark the CPT+DQMC method for the attractive and repulsive Hubbard models, showcasing its advantages over standard DQMC and CPT+ED simulations.

show abstract

“…Calculations of the 2D Hubbard model have found a pseudogap in the single-particle spectra, with properties closely resembling those of photoemission and tunneling spectra of cuprates . These include its extent in the temperature-doping phase diagram [3,6,18,22,23,32] and the contrasting behaviors in the anti-nodal and nodal regions of the Brillouin zone, leading to the phenomena of Fermi arcs [12,14,15,20,21,25,31,32]. Apart from single-particle properties, other important aspects of pseudogap phenomenology in cuprate have been found and studied in the Hubbard model, including suppression of the spin susceptibility [6,28,[33][34][35][36] and presence of spin and charge density waves [37][38][39].…”

mentioning

confidence: 99%

“…First, most of these calculations involve solving a small cluster that is part of the infinite system, via a generalization of dynamical mean-field theory or by cluster perturbation theory (CPT). Some of these, such as the CPT calculations in [10,25,27,32], do not permit long-range order, implying that short-range correlations are sufficient for generating the pseudogap. Viewed as simulations of the Hubbard model, such calculations are incorrect in the sense that they do not produce low-temperature ordered phases.…”

mentioning

confidence: 99%

Strong-coupling mechanism of the pseudogap in small Hubbard clusters

Huang

2020

Preprint

View full text Add to dashboard Cite

In the hole-doped cuprates, the pseudogap refers to a suppression of the density of states at low energies, in the absence of superconducting long-range order. Numerous calculations of the Hubbard model show a pseudogap in the single-particle spectra, with striking similarities to photoemission and tunneling experiments on cuprates. However, no clear mechanism has been established. Here, we solve the Hubbard model on 2 × 2 clusters by exact diagonalization, with integration over twisted boundary conditions. A pseudogap is found in the single-particle density of states with the following characteristics: a decreasing energy scale and onset temperature for increased hole-doping, closure at a critical hole doping near 15%, absence upon electron-doping, particle-hole asymmetry indicated by the location of the gap center, and persistence in the strong-coupling limit of U/t → ∞. Studying the many-body excitation spectrum reveals that the pseudogap in single-particle spectra is due to orthogonality between bare electrons and the lowest energy excitations for U/t 8.

show abstract

Doping and temperature evolution of pseudogap and spin-spin correlations in the two-dimensional Hubbard model

Cited by 13 publications

References 97 publications

Polaron transformations in the realistic model of the strongly correlated electron system

Polaron transformations in the realistic model of the strongly correlated electron system

Determinantal Quantum Monte Carlo solver for Cluster Perturbation Theory

Strong-coupling mechanism of the pseudogap in small Hubbard clusters

Contact Info

Product

Resources

About