Thermal evolution of antiferromagnetic correlations and tetrahedral bond angles in superconductingFeTe1−xSex

Abstract: It has recently been demonstrated that dynamical magnetic correlations measured by neutron scattering in iron chalcogenides can be described with models of short-range correlations characterized by particular choices of four-spin plaquettes, where the appropriate choice changes as the parent material is doped towards superconductivity. Here we apply such models to describe measured maps of magnetic scattering as a function of two-dimensional wave vectors obtained for optimally superconducting crystals of FeTe1… Show more

“…For the theory to be consistent, it is important that it should be able to describe not only the lack of magnetic ordering in FeSe, but also the appearance of magnetism under applied pressure and with Te doping. In this paper, we show that the recently proposed theory of the spin ferroquadrupolar (FQ) ground state for FeSe [25] indeed satisfies these requirements and successfully describes the evolution of the INS data as a function of Te doping in Fe(Te 1−x Se x ), in qualitative accord with the recent INS experiments [11].…”

“…Remarkably, it was found that in nonsuperconducting Fe(Te 1−x Se x ) samples (due to excess of Fe), the magnetic correlations remain pinned at (π/2,π/2) [11]. The authors of Ref.…”

“…Intriguingly, the neutron spin structure in superconducting Fe(Te 1−x Se x ) samples undergoes a complicated transformation as a function of temperature, with the hightemperature data (T 100 K) characterized by the DS wave vector (π/2,π/2) and evolving to Q 1,2 upon cooling [11]. Remarkably, it was found that in nonsuperconducting Fe(Te 1−x Se x ) samples (due to excess of Fe), the magnetic correlations remain pinned at (π/2,π/2) [11].…”

“…This state is in stark contrast to the parent compounds of iron pnictides that have a columnar antiferromagnetic (CAFM) ground state [4][5][6]. Upon doping with selenium, the DS magnetism disappears, resulting in a nonmagnetic ground state in Fe(Te 1−x Se x ) (for sufficiently large x) [7][8][9][10][11]. The nature of this state, extending all the way to the stoichiometric FeSe, has been the subject of intense debate recently, with elastic neutron scattering showing no sign of magnetic Bragg peaks in FeSe [12,13].…”

“…In this paper, we show that including the third-neighbor Heisenberg interaction J 3 is necessary to describe the DS magnetic state of Fe 1+y Te and that the increasing J 3 strength describes qualitatively the effect of Te doping in Fe(Te 1−x Se x ). Using the variational mean-field, flavor-wave expansion and the DMRG calculations, we compute the phase diagram and establish that the evolution of the calculated dynamic spin-structure factor S(q,ω) with increasing J 3 mimics that observed in INS data in Fe(Te 1−x Se x ) [11]. Crucially, the obtained phase diagram naturally describes both this evolution and the tendency towards the CAFM ordering under the applied pressure in FeSe [18][19][20][21] within a single unified theory.…”

Unified spin model for magnetic excitations in iron chalcogenides

“…For the theory to be consistent, it is important that it should be able to describe not only the lack of magnetic ordering in FeSe, but also the appearance of magnetism under applied pressure and with Te doping. In this paper, we show that the recently proposed theory of the spin ferroquadrupolar (FQ) ground state for FeSe [25] indeed satisfies these requirements and successfully describes the evolution of the INS data as a function of Te doping in Fe(Te 1−x Se x ), in qualitative accord with the recent INS experiments [11].…”

“…Remarkably, it was found that in nonsuperconducting Fe(Te 1−x Se x ) samples (due to excess of Fe), the magnetic correlations remain pinned at (π/2,π/2) [11]. The authors of Ref.…”

“…Intriguingly, the neutron spin structure in superconducting Fe(Te 1−x Se x ) samples undergoes a complicated transformation as a function of temperature, with the hightemperature data (T 100 K) characterized by the DS wave vector (π/2,π/2) and evolving to Q 1,2 upon cooling [11]. Remarkably, it was found that in nonsuperconducting Fe(Te 1−x Se x ) samples (due to excess of Fe), the magnetic correlations remain pinned at (π/2,π/2) [11].…”

“…This state is in stark contrast to the parent compounds of iron pnictides that have a columnar antiferromagnetic (CAFM) ground state [4][5][6]. Upon doping with selenium, the DS magnetism disappears, resulting in a nonmagnetic ground state in Fe(Te 1−x Se x ) (for sufficiently large x) [7][8][9][10][11]. The nature of this state, extending all the way to the stoichiometric FeSe, has been the subject of intense debate recently, with elastic neutron scattering showing no sign of magnetic Bragg peaks in FeSe [12,13].…”

“…In this paper, we show that including the third-neighbor Heisenberg interaction J 3 is necessary to describe the DS magnetic state of Fe 1+y Te and that the increasing J 3 strength describes qualitatively the effect of Te doping in Fe(Te 1−x Se x ). Using the variational mean-field, flavor-wave expansion and the DMRG calculations, we compute the phase diagram and establish that the evolution of the calculated dynamic spin-structure factor S(q,ω) with increasing J 3 mimics that observed in INS data in Fe(Te 1−x Se x ) [11]. Crucially, the obtained phase diagram naturally describes both this evolution and the tendency towards the CAFM ordering under the applied pressure in FeSe [18][19][20][21] within a single unified theory.…”

Unified spin model for magnetic excitations in iron chalcogenides

Electronic properties of the bulk and surface states of Fe1+yTe1−xSex

Nematic fluctuations in an orbital selective superconductor Fe1+yTe1−xSex